KR101349607B1 - Biometrics device - Google Patents

Abstract

The present invention relates a biometrics device. The present invention enables biometric tasks by transmitting and receiving wireless signals; improves transmitting and receiving efficiency for wireless biometrics signals. According to this, the present invention enables users to run biometric tasks without adjusting the angle of incidence when using a prism and without damaging a biometric information input window.

Description

Biometrics device

The present invention relates to a biometric device, and more particularly, to a biometric device that improves the transmission and reception efficiency of a radio signal for recognizing biometric information (eg, fingerprint, iris, etc.).

With the advent of the information age, a security system for protecting various information such as corporate information, personal information and financial information has emerged as a very important problem.

As a security system, devices using information accessor's own password, ID card, mobile phone's unique information, etc. have been used, but there are many problems due to the possibility of duplication and theft.

Due to these problems, there has been a need for a biometric device with enhanced security functions such as iris data, fingerprint data, and voice recognition data that are difficult to reproduce and steal. Such biometric devices typically have specific parts of the body (eg, finger fingerprints). And a prism having an input window contacting (or non-contacting) the iris, a sensor unit sensing a light source reflected from an inner surface of the prism, and comparing the stored light source with biometric information after scanning the light source detected from the sensor unit. It consists of an authentication part, Unexamined Patent Publication No. 2004-0041284 (published 2004.05.17.), Publication No. 2008-0029442 (published date 2008.04.03.), Publication No. 2010-0009260 (published) 2010.01.27.

However, such a biometric device of the fingerprint scans the reflected light source when the light source is incident on the inner surface of the prism, that is, the incident surface and reflected through the ridge of the fingerprint when the fingerprint touches the input window of the prism. When the light source is incident on the incident surface of the light source and reaches the input window formed on the outer surface of the prism, due to the scattering phenomenon of the light source passing between the incident surface and the input window, the reflection of the light source in the ridge portion of the fingerprint is properly In many cases, the recognition unit did not properly scan the biometric information, that is, the biometric information recognition rate was low.

Accordingly, in the related art, the recognition rate of the biometric information is increased by applying a chemical or a pad to the external surface input window of the prism. However, even in this case, the sensitivity of the light source is increased from the inner incident surface of the prism to the external input window. Since it does not increase, the rate of recognizing biometric information through the light source reflected from the ridge of the fingerprint is inevitably lowered.

Accordingly, the present invention is to improve the conventional problems as described above, and to provide a biometric recognizer to increase the transmission and reception efficiency of the radio signal for the recognition of the biometric information as well as to perform the biometric information transmission and reception of the radio signal. The purpose is.

Biometric information present invention for achieving the above object, Biometric information input window exposed to the outside, the biometric information is in contact or non-contact; A wireless signal transmitting / receiving unit which is located inside and transmits a first wireless signal passing through the biometric information input window and receives a second wireless signal transmitted by biometric information contacted or non-contacted with the biometric information input window; And an authentication unit configured to recognize biometric information from the second radio signal received from the radio signal transceiver, and to determine whether to authenticate the biometric information by comparing the recognized biometric information with previously stored biometric information. .

In addition, the biometric information input window comprises a plate-shaped protection window made of glass or sapphire, wherein the protection window is the sensitivity of the first radio signal by the radio signal transceiver and the contact or non-contact with the protection window A coating layer having a constant dielectric constant is formed to increase the sensitivity of the second wireless signal transmitted by the biometric information.

In addition, the coating layer is a coating of any one material of titanium dioxide (TiO2), barium titanate (BaTiO3), ceramic on the surface of the protective window.

The coating layer is formed by bonding a material made of any one of titanium dioxide (TiO 2), barium titanate (BaTiO 3), and ceramic to the surface of the protective window.

The authentication unit may include a calculation program that calculates a transmission distance of the first radio signal and a reception distance of the second radio signal to recognize biometric information.

In addition, the biometric information is a fingerprint contacting the biometric information input window or a non-contact iris which is a predetermined distance from the biometric information input window.

As described above, the present invention is to configure the biometric recognizer to increase the transmission and reception efficiency of the radio signal for the recognition of the biometric information, as well as to perform the biometric information transmission and reception of the radio signal, thereby eliminating the incident angle adjustment work when using the prism In order to prevent damage to the biometric information input window, stable biometric information recognition can be achieved.

1 is a block diagram showing the structure of a biometric reader in an embodiment of the present invention.
Figure 2 is a cross-sectional view showing the structure of the protective window applied to the biometric reader in an embodiment of the present invention.
Figure 3 is a state diagram of use of fingerprint recognition in an embodiment of the present invention.
Figure 4 is a state of use of iris recognition in an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

1 is a block diagram showing a structure of a biometric reader according to an embodiment of the present invention, Figure 2 is a cross-sectional view showing a structure of a protective window applied to the biometric reader in an embodiment of the present invention, Figure 3 is an embodiment of the present invention 4 is a diagram illustrating a state of use of fingerprint recognition, and FIG. 4 is a diagram illustrating a state of use of iris recognition according to an embodiment of the present invention.

1 to 4, a biometric device according to an embodiment of the present invention includes a biometric information input window 10, a non-signal transmitting / receiving unit 20, and an authenticating unit 30.

The biometric information input window 10 is externally exposed so that the biometric information such as a fingerprint is in contact or the non-contact such that the biometric information such as the iris is approached by a certain distance, and includes a protective window 11 and a coating layer 12. will be.

The protective window 11 is a plate-shaped structure, which is made of sapphire or glass that prevents breakage even when an external impact is applied although a disturbance (eg scattering phenomenon) occurs when the radio signal RF is transmitted. .

The coating layer 12 is made of glass or sapphire to compensate for the occurrence of obstacles in the transmission of the radio signal, the sensitivity of the first radio signal (TX) by the radio signal transceiver 20, and the protective window 11 Apply a material of any one of titanium dioxide (TiO 2), barium titanate (BaTiO 3) and ceramics having a constant dielectric constant to increase the sensitivity of the second radio signal RX transmitted by the biometric information contacted or non-contacted It is formed by bonding a material made of any one of titanium dioxide (TiO 2), barium titanate (BaTiO 3), and ceramic.

That is, in the embodiment of the present invention to configure a protective window 11 in the form of a plate made of glass or sapphire, while forming a coating layer 12 which is coated by the application of a material having a high dielectric constant or the adhesion of the material to the surface By increasing the transmission and reception efficiency of the radio signal by the radio signal transmission and reception unit 20, while the biological information input window 10 consisting of the protective window 11 and the coating layer 12 from the impact applied from the outside It is to protect more effectively.

The radio signal transceiver 20 transmits a first radio signal TX that transmits the biometric information input window 10 and transmits the biosignal information that is in contact or non-contact with the biometric information input window 10. After receiving the second radio signal (RX) is configured to deliver it to the authentication unit (30).

The authentication unit 30 is located on the inner side of the biometric information input window 10 based on the biometric information input window 10, and the ridges and valleys of the fingerprint from the wireless signal transceiver 20 The biometric information is recognized from the second wireless signal RX reflected and received according to the curved shape of the iris, and the biometric information is compared with the biometric information which is a stored reference to determine whether to authenticate. The unit 30 calculates the transmission distance of the first radio signal TX and the reception distance of the second radio signal RX to recognize the shape of the ridge of the fingerprint as the biometric information and the curve of the bone or the iris as the biometric information. The calculation program is installed so that it can be done.

As such, the biometric device according to the embodiment of the present invention has a high dielectric constant of titanium dioxide (TiO 2) on the plate-shaped protective window 11 made of glass or sapphire for secure access, as shown in FIGS. 1 to 4. , The barium titanate (BaTiO 3), the biological information input window 10 having the coating layer 12 formed by coating a material of any one of ceramic or adhesion of the material to contact the fingerprint or close the iris.

Then, when the fingerprint contact or the iris close to the biometric information input window 10, the wireless signal transceiver 20 located inside the biometric information input window 10 transmits a first radio signal TX to the biometric information input window 10. The information input window 10 is transmitted.

In this case, the sensitivity of the protective window 11 made of sapphire is increased by the coating layer 12 having the high dielectric constant of the first wireless signal TX. Accordingly, the first wireless signal transmitted through the protective window 11 is increased. (TX) reaches the fingerprint or the iris.

In addition, the second wireless signal RX that reaches the fingerprint or the iris and is reflected is plate-shaped protective window 11 made of glass or sapphire by the high dielectric constant coating layer 12 included in the biometric information input window 10. After passing through) is received by the wireless signal transceiver 20.

At this time, the wireless signal transmission and reception unit 20 is to transmit the second wireless signal (RX) received by reflecting from the fingerprint or iris to the authentication unit 30,

The authentication unit 30 recognizes the biometric information from the second radio signal RX received from the radio signal transceiver 20 through the operation of the operation program, and the biometric information is the stored biometric information as a reference. In comparison, the security access is approved or denied.

That is, the calculation program of the authentication unit 30 is a transmission distance at which the first radio signal TX transmitted from the radio signal transceiver 20 reaches the ridge and the valley of the fingerprint through the biometric information input window 10. Or a transmission distance for reaching a curved iris, and a reception distance of a second wireless signal RX reflected from a ridge and a valley of the fingerprint, or a reception of a second wireless signal RX reflected from the iris that forms a curved line. It calculates the distance to recognize the biometric information of the fingerprint or iris that is in contact or non-contact with the biometric information input window 10, based on the curved shape of the ridge of the fingerprint that is the recognized biometric information and the bone or iris of the biometric information Compared with the ridge of the fingerprint, which is the stored reference biometric information, and the curve of the bone or iris, it is determined whether security access is allowed.

Although the technical concept of the biometric device of the present invention has been described above with the accompanying drawings, this is illustrative of the best embodiment of the present invention and is not intended to limit the present invention.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention as defined by the appended claims. It is to be understood that such changes and modifications are within the scope of the claims.

10; Biometric information input window 11; Protective window
12; Coating layer 20; Wireless signal transceiver
30; Authentication unit

Claims (6)

A biometric information input window exposed to the outside and contacting the fingerprint as the biometric information or the iris as the biometric information without contact;
A first wireless signal which is located inside and transmits the first wireless signal penetrating the biometric information input window, and is reflected and transmitted according to the curved shape of the iris which is the biometric information that is bone or non-contact with the ridge of the fingerprint contacting the biometric information input window A wireless signal transmission and reception unit for receiving two wireless signals; And
Recognizing the curved shape of the ridges and bones or biometric information of the fingerprint and the curved shape of the ridges and bones or iris of the fingerprint that is the recognized biometric information from the second wireless signal received from the wireless signal transmission and reception unit An authentication unit which determines whether to be authenticated by comparing the ridge of the fingerprint, which is the biometric information that is previously stored, and the curve of the bone or iris; Biometric device, characterized in that comprising a. The method of claim 1, wherein the biometric information input window,
And a plate-shaped protective window made of glass or sapphire, wherein the protective window has a second radio transmitted through the sensitivity of the first radio signal by the radio signal transceiver and the biometric information in contact or non-contact with the protective window. A biometric device characterized in that to form a coating layer having a constant dielectric constant to increase the sensitivity of the signal. The biorecognizer of claim 2, wherein the coating layer is formed by applying any one of titanium dioxide (TiO 2), barium titanate (BaTiO 3), and ceramic to the surface of the protective window. The biometric device of claim 2, wherein the coating layer is formed by adhering a material made of any one of titanium dioxide (TiO 2), barium titanate (BaTiO 3), and ceramic to the surface of the protective window. The method of claim 2, wherein the authentication unit transmits the first radio signal to recognize a curved shape of the ridge contacting the biometric information input window and the iris or bone or the iris approaching the biometric information input window in a non-contact state at a predetermined distance. And a calculation program for calculating a distance and a reception distance of the second radio signal. delete

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