KR20190041349A - Anti-spoofing method and system of a device having a fingerprint sensor - Google Patents

Abstract

According to a disclosure of the present invention, disclosed is an anti-spoofing method using a device including a fingerprint sensor. More specifically, provided are the anti-spoofing method which measures oxygen saturation while recognizing a user fingerprint at the same time so as to enhance the security of a device, by arranging optical characteristics of some regions of a cut filter layer of an optical fingerprint sensor to measure the oxygen saturation; and the device for performing the anti-spoofing method.

Description

TECHNICAL FIELD [0001] The present invention relates to an anti-spoofing method and system for a device including a fingerprint sensor,

The present invention relates to a method and system for preventing spoofing of a mobile device using a user's body information using a fingerprint recognition sensor. More particularly, the present invention relates to a method and apparatus for efficiently supporting anti-spoofing by measuring a user's oxygen saturation using a PPG sensor module (optical sensor module) mounted on a mobile terminal.

Because of the widespread use of satellite positioning systems by fixed and mobile communication systems, including mobile terminals, such as cellular telephones, " spoofing ", which is the use of counterfeit positioning signals to provide a false location to a device, have.

For example, WLAN AP (Access Point) spoofing attacks another system by tricking the sending IP address when transmitting packets, so an attacker can hide his information and avoid detection. In other words, the WLAN AP spoofing can easily disable the authentication service between two systems in the trust relationship by authenticating only the IP address, since the unauthorized person tricks his / her IP address into the IP address of the trusted host .

On the other hand, fingerprints have uniqueness, uniqueness and convenience that are unusual characteristics of human body and do not change forever. Currently, fingerprint identification technology has been widely applied to devices such as collection systems, access control systems, and smart phones. Capacitive fingerprint identification technology has been widely used in application functions such as unlocking fingerprints of mobile phones, The demand for safety of fingerprints is also increasing. Capacitive-based fingerprint identification technology can break the fingerprint identification capabilities of various mobile phone models by printing fake fingerprints using special materials that can be cracked and acquire fingerprint images. Therefore, more secure fingerprint identification technology is needed.

One type of portable bio-signal measuring device is a photoplethysmographic (PPG) measuring device. Since the information about the degree of shrinkage of the peripheral blood vessels and the increase / decrease of the cardiac output is reflected on the optical pulse wave, the physiological state related to the arterial blood vessel can be grasped and it can be mainly used as a diagnostic assistant for a specific disease.

Generally, the PPG signal can be measured from the user's finger or earlobe. That is, the detector detects the light transmitted through the finger or the earlobe from the light source, thereby detecting the user's PPG signal.

Japanese Patent Laid-Open Publication No. 2006-074104 (published on Mar. 16, 2006)

The present invention provides a method of performing anti-spoofing using fingerprint information, which is biometric information of a user, in order to prevent erroneous authentication caused by a user who is misunderstood by spoofing.

The present invention provides a device for performing anti-spoofing through a fingerprint sensor by means of a fingerprint sensor. The device includes a biometric sensor for detecting a plurality of biometric information of a user at the same time, A security information generator for generating user security information by combining the user's security information and the degree of oxygen saturation, a memory for storing information on the biometric information of the registered user in advance, and a biometric information generator for comparing the user security information with biometric information of a user registered in advance, The biosensor may include a fingerprint sensor that senses a user's fingerprint image and a PPG (Photo-plethysmography) sensor that measures oxygen saturation of the user.

According to one aspect of the present invention, the present invention can provide an anti-spoofing method using a device including a fingerprint sensor, which uses a biosensor included in one side of a device to simultaneously sense a plurality of biometric information of a user Generating user security information by combining fingerprint images and oxygen saturation obtained from the biometric sensor and comparing the user security information with biometric information of a user registered in advance to determine whether the user is authentic, The sensor may be characterized by a combination of a fingerprint sensor that senses the user's fingerprint image and a PPG (Photo-plethysmography) sensor that measures oxygen saturation of the user.

And may include a recording medium on which a program necessary for executing the method of the present invention is recorded by another embodiment.

The security of the mobile terminal can be enhanced by detecting whether the fingerprint is fingerprinted using the biometric identification information and the oxygen saturation.

The mobile device is provided with a function for simultaneously performing the oxygen saturation measurement and the user authentication by the start of the operation, the oxygen saturation is measured using the mobile device, and the fingerprint of the finger is recognized to perform the identity authentication. Therefore, the user can be authenticated at the same time while measuring the oxygen saturation simply and conveniently without requiring a separate oxygen saturation measuring device, thereby realizing user authentication more efficiently and stably.

In addition, according to the present invention, it is possible to prevent a spoofing attack by fingerprint recognition because the accuracy of checking the correspondence between the registered fingerprint of the user and the recognized fingerprint is increased.

The present invention can double security by using the fingerprint as well as the user's oxygen saturation, thereby enhancing the security of the device. In addition, since a filter having two optical characteristics is installed in one filter, it is possible to sense user biometric information in a complex manner, which is economical and efficient.

1 is a diagram for explaining a device including a fingerprint sensor of the present invention.
2 is a diagram for explaining a configuration of a device for performing anti-spoofing according to an embodiment of the present invention.
3 is a view for explaining the structure of a biosensor according to an embodiment of the present invention.
4 is a diagram for explaining a configuration of a device including a pinhole layer according to an embodiment.
5 is a diagram for comparing characteristics of a red signal and a characteristic of a near-infrared signal according to an embodiment.
FIG. 6 is a diagram showing a change in oxygen saturation according to a signal ratio according to an embodiment.
FIG. 7 is a graph showing a change in light absorption coefficient according to one embodiment of the present invention. FIG.
8 is a view for explaining a method of detecting a counterfeit fingerprint according to an embodiment.
9 is a view for explaining a feature of a pixel of a fingerprint sensor according to an embodiment.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Also, in order to clearly illustrate the present invention in the drawings, portions not related to the present invention are omitted, and the same or similar reference numerals denote the same or similar components.

The objects and effects of the present invention can be understood or clarified naturally by the following description, and the objects and effects of the present invention are not limited only by the following description.

The objects, features and advantages of the present invention will become more apparent from the following detailed description. In the following description, well-known functions or constructions are not described in detail since they would obscure the invention in unnecessary detail. Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a diagram for explaining a device including a fingerprint sensor of the present invention. The device 100 includes a touch panel assembly including a biosensor. The device 100 includes another sensor 21 such as a camera. The device 100 may also include various buttons, such as side buttons, which accept user input. The touch panel assembly 10 may include a reinforcement cover glass 50 disposed on the support glass 54. A colored epoxy material layer 52 may be used to attach the cover glass 50 to the support glass 54. The ITO pattern 56 may be printed on the bottom surface or the back surface of the supporting glass 54. The support glass may be arranged to form a hole 58 for receiving the fingerprint sensor module or device 20.

When a fingerprint is recognized, an optical sensing device such as a photodiode and a light source such as a light emitting diode (LED) and a laser diode (LD) May be integrated into the device in other manners.

A biosensor for recognizing a fingerprint can be designed to be applied to the front of the display or to a specific location of the device.

2 is a diagram for explaining a configuration of a device for performing anti-spoofing according to an embodiment of the present invention.

It is possible to provide the device 100 that performs anti-spoofing through the fingerprint sensor by means of the initiation.

In addition, the biometric sensor 110 included in one side of the device 100 and sensing a plurality of biometric information of the user at the same time can be provided.

The security information generating unit 120 may generate the user security information by combining the fingerprint image and the oxygen saturation obtained from the biometric sensor by the start of operation.

It is possible to provide the memory 130 for storing information on the biometric information of the user registered in advance by the start of operation.

The falsification determining unit 140 may compare the user security information and the biometric information of the user registered in advance to determine whether the user is authentic or not.

The biometric sensor 110 may include a fingerprint sensor 111 for sensing a fingerprint image of a user and a PPG (Photo-plethysmography) sensor 112 for measuring oxygen saturation of the user.

The present invention also provides a differential CV amplifier for amplifying a PPG signal through a PPG sensor, a sample amplifier for separating the PPG signal into an IR signal and a RED signal, a peripheral amplifier for removing an ambient noise signal, And measuring the oxygen saturation of the user.

The light emitting unit may include at least one of an internal light source located in the display panel of the device 100 and emitting light, or an external light source positioned in the display cover glass of the device 100 to emit light.

The biometric sensor is composed of a touch sensor grouped by a plurality of fingerprint sensor 111 pixels. The falsification determining unit 140 determines whether or not the data obtained from each of the plurality of fingerprint sensor 111 pixels And the user security information generated by the user security information may be used.

The falsification determining unit 140 compares the fingerprint image of the user with the fingerprint image registered in advance to derive a first falsification judgment value to determine whether the coincidence rate of the fingerprint pattern is higher than a predetermined reference, Comparing the oxygen saturation of the blood to determine whether the error value corresponds to a predetermined reference value, deriving a second falsification judgment value, and determining whether the user is authentic using the first falsification judgment value and the second falsification judgment value have.

Accordingly, in the present invention, it is possible to first determine whether the user forged is first forged using fingerprints, determine the authenticity of the user, and then determine whether the user is a second-forged user by using oxygen saturation, which is another user information. Further, the fingerprint and oxygen saturation information can be combined and judged at one time. Security can be enhanced by using complex information.

Therefore, device security can be effectively implemented using pre-registered user information.

In addition, a fingerprint image quality evaluation unit for dividing a fingerprint image of a user into blocks to determine a picture quality evaluation value, a filtering unit for filtering the fingerprint image of the user to obtain a filtered fingerprint image, A fingerprint comparison unit for comparing the image with a fingerprint image registered in advance to determine a similarity value, and a fingerprint authenticity determination unit for determining whether the fingerprint of the user is falsified based on the determined image quality evaluation value and the similarity value.

The above configurations can be integrally performed by the control unit. The control unit may refer to a module for collectively controlling the device 100 of the present invention.

The apparatus further comprises a finger recognition sensor for sensing the user's finger when the fingerprint is touched by the biometric sensor and an actual user determination circuit for determining whether the fingerprint image is fingerprint of the user's actual finger .

It is possible to judge whether the person who touches the fingerprint by using the finger recognition sensor is an actual person or another object that forged the fingerprint, and security can be enhanced.

3 is a view for explaining the structure of a biosensor according to an embodiment of the present invention.

The biometric sensor 110 may be configured such that a fingerprint recognizing part and a user's part for measuring oxygen saturation of the user are combined.

The fingerprint sensor 111 is provided with a light emitting unit for irradiating light of a specific frequency to a user's fingerprint area and light of a specific frequency reflected by the user's fingerprint by the photodiodes formed by a plurality of sensor pixels And a fingerprint image generating unit for generating a fingerprint image through signal processing on the electric signal.

The PPG sensor 112 is a color filter for selectively passing light of the same color so as to selectively sense light having the same color and wavelength band with respect to a part of photodiodes included in the light receiving unit of the fingerprint sensor 111. [ (Color Pass Filter) and an infrared ray filter (IR Pass Filter) for selectively passing light having the same wavelength band in the infrared region in order to selectively sense light having the same wavelength band in the infrared region have.

The fingerprint sensor 111 is provided with an optical filter (Red-IR Cut Filter) for blocking light of an infrared band or more on the remaining photodiodes except the color filters and the photodiodes equipped with the infrared filter among the photodiodes of the light receiving unit And the like.

3, the structure of the living body sensor 110 can be confirmed.

In the case of the optical fingerprint sensor, it is necessary to secure an optical filter layer on the top of the fingerprint sensor, which can remove the near infrared ray band in order to secure authentication performance in the outdoor light.

Also, in order to perform complex user authentication pursued by the present invention, it is necessary to be able to simultaneously measure oxygen saturation of blood. At this time, in order to sense blood oxygen saturation or HRM, red color and near infrared ray band light are required. Therefore, a filter capable of transmitting red color and near infrared ray band light is required inside the optical filter layer serving as a cut filter

Accordingly, a red-IR cut filter 2020 can be formed on the plurality of photodiodes 2010 constituting the fingerprint sensor. In order to measure the oxygen saturation of blood in the Red-IR cut filter 2020, an IR Pass Filter (2030) and Red Pass Filter (2040).

That is, the light passing through the IR Pass Filter 2030 and the Red Pass Filter 2040 is analyzed to determine the oxygen saturation of the blood, and the user's fingerprint information is determined using the light passed through the other Red-IR cut filter 2020 Can be identified.

Therefore, the present invention can double security by using the user's oxygen saturation as well as the fingerprint, thereby enhancing the security of the device. In addition, since a filter having two optical characteristics is installed in one filter, it is possible to sense user biometric information in a complex manner, which is economical and efficient.

4 is a diagram for explaining a configuration of a device including a pinhole layer according to an embodiment.

4, the device 100 includes a display panel 3110 and a fingerprint sensor 2120, and the fingerprint sensor 2120 may include a pinhole layer 3200 and a biometric sensor 110. According to one embodiment, the fingerprint sensor 2120 may be packaged and attached to one side of the display panel 3110.

The pinhole layer 3200 includes a plurality of pinholes, and each pinhole can form a focus of light reflected and transmitted by the fingerprint. In addition, the display panel 3110 may include LEDs emitting light of a plurality of colors. Also, LEDs emitting light at least a part of the plurality of colors among the LEDs may be used for the fingerprint sensing operation.

The biological sensor 110 includes a plurality of sensor pixels corresponding to a plurality of pinholes, and each sensor pixel may include one or more photodiodes PD. Also, according to one embodiment, a filter may be formed corresponding to each of the plurality of sensor pixels, and the same color filter (or a filter that passes light of the same wavelength) may be formed corresponding to the sensor pixels have. In the embodiment of FIG. 4, a red color filter CF_R corresponding to the sensor pixel is formed above the photodiode in the image sensor.

Further, there is shown an example of a sensor pixel in which a near-infrared filter IF for efficiently passing near-infrared rays is formed. Further, the remaining photodiodes can be applied with an optical filter capable of blocking light having a wavelength longer than that of the near-infrared band.

4, even if the light from all the LEDs of the display panel 3110 is reflected on the fingerprint, the same color (or the same color) is output through the mono filter that filters the same color in the bio- Wavelength) can be selectively provided to the photodiodes (PD) in the sensor pixel, the sharpness of the result of the fingerprint sensing can be improved similarly to the above-described embodiment.

4, the oxygen saturation of the user can be measured using light in the infrared region passed through the near-infrared filter and light passing through the red filter. The present invention also provides a differential CV amplifier for amplifying a PPG signal through a PPG sensor, a sample amplifier for separating the PPG signal into an IR signal and a RED signal, a peripheral amplifier for removing an ambient noise signal, And measuring the oxygen saturation of the user.

The pinhole layer can be positioned between the display panel and the biosensor by virtue of the initiation. In addition, the pinhole layer may include a plurality of pinholes that form a focus for transmitting light reflected by the user's fingerprint to the biosensor.

The plurality of pinholes may be arranged to correspond one-to-one with a plurality of biosensor pixels included in the biosensor.

5 is a diagram for comparing the characteristics of the red signal and the characteristics of the near-infrared signal.

Referring to FIG. 5, the components of the red signal passing through the skin and the components of the near-infrared signal are shown. Both the red signal and the near-infrared signal passing through the skin are composed of DC component and AC component. In particular, the DC component of the near-infrared signal is larger than the DC component of the red signal, and the AC component of the near-infrared signal is larger than the AC component of the red signal. Oxygen saturation utilizes the difference between the response of oxygen hemoglobin and hemoglobin to the red signal and the near-infrared signal, and uses the ratio of the signal calculated as follows.

(Wherein, R is the ratio of the red signal and the near infrared signal, S _R is the red signal, S _IR is a near infrared signal, AC _R is the AC component of the red signal, DC _R is the DC component of the red signal, AC _IR is a near-infrared signal AC Component, DC _IR is the DC component of the near infrared signal)

6 is a diagram showing a change in oxygen saturation according to a signal ratio.

Referring to FIG. 6, the change in oxygen saturation according to the ratio of the red signal to the near-infrared signal is shown. That is, the oxygen saturation decreases as the size of the red signal increases as compared with the near-infrared signal, and the oxygen saturation increases as the size of the red signal decreases as compared with the near-infrared signal. On the other hand, oxygen saturation is a criterion for judging cardiac function and pulmonary function, and normal people have oxygen saturation near 100. On the other hand, the relationship between the ratio of the red signal to the near-infrared signal and the oxygen saturation is as follows.

(Where SpO ₂ is oxygen saturation, A is a y-intercept, B is a slope, and R is a ratio of signals)

7 is a graph showing the change of the light absorption coefficient according to the wavelength.

Referring to FIG. 7, changes in the optical absorption coefficient of oxygen hemoglobin and hemoglobin with respect to wavelength are shown. That is, it can be seen that the light absorption coefficient of oxygen hemoglobin is larger than that of hemoglobin for a signal with a small wavelength, and the light absorption coefficient of oxygen hemoglobin is smaller than that of hemoglobin for a signal having a large wavelength. In particular, it can be seen that the difference in the optical absorption coefficient between oxygen hemoglobin and hemoglobin varies considerably even if the wavelength is slightly changed for a red signal having a wavelength of 640 to 690 nm.

The user can simultaneously recognize the oxygen saturation and the fingerprint using the biosensor of the present invention.

Oxygen saturation can be measured on the photodiode of the fingerprint sensor with a red color filter and a PPG sensor equipped with an infrared pass filter. This will be described in more detail below.

A photodiode equipped with a red color filter is referred to as a first light emitting element, and a photodiode having an infrared filter equipped with an in-pass filter is referred to as a second light emitting element.

And the light output of the red signal can be performed in the first light emitting device. Further, the red light signal can be detected through the red light receiving element. The first photodetection data detected by the light receiving element can be stored in the memory. In addition, the current I ₂ applied to the second light emitting element can be increased by a unit size. Further, the second light emitting device can perform light output of the near-infrared light signal. It is possible to perform optical detection of a near-infrared signal using a light receiving element. And the second photodetection data detected by the light receiving element can be stored in the memory. Where the unit size may be in units of A.

It is determined whether the current I ₁ applied to the first light emitting element and the current I ₂ applied to the second light emitting element have reached the set values respectively and if the first current I ₁ and the second current I ₂ The first current I ₁ can be increased by the unit magnitude, the second current I ₂ can be further increased by the unit magnitude, and the current can be further increased. That is, the first current I ₁ and the second current I ₂ can be continuously increased until valid data necessary for analyzing the characteristics of the oxygen saturation measuring sensor is obtained.

If the first current I ₁ and the second current I ₂ respectively reach the set values, the first photodetection data and the second photodetection data can be analyzed.

That is, the rate of change of the first photodetection data value according to the increase of the first current I ₁ is analyzed (first analysis), and the rate of change of the second photodetection data value with the increase of the second current I ₂ is calculated (Second analysis). The difference between the rate of change of the first photodetection data value with the increase of the first current I ₁ and the rate of change of the second photodetection data value with the increase of the second current I ₂ is analyzed ). It is also possible to analyze the value of the first photodetection data for the first current I ₁ having a specific magnitude (fourth analysis) and calculate the second photodetection data for the second current I ₂ having the same magnitude The value is analyzed (Fifth analysis). The difference between the values of the second photodetection data for the second current (I ₂ ) having the same magnitude as the value of the first photodetection data for the first current (I ₁ ) having a specific magnitude is analyzed 6 analysis).

Based on the results of the analysis, it is possible to modify the previously stored oxygen saturation calculation method. That is, the oxygen saturation measurement algorithm (Equations 1 and 2) is modified to be suitable for an oxygen saturation measuring sensor having a new light output characteristic. Modification of the oxygen saturation measurement algorithm can be performed comprehensively based on the first to sixth analysis results. On the other hand, as described above, since the wavelength change of the red signal has the greatest influence of oxygen saturation, the oxygen saturation measurement algorithm can be modified based on the first analysis and the fourth analysis. The microprocessor stores the modified oxygen saturation calculation method in a memory, and calculates the oxygen saturation with reference to the corrected oxygen saturation calculation method.

8 is a view for explaining a method of detecting a counterfeit fingerprint according to an embodiment.

The falsification determining unit 140 according to one embodiment includes a fingerprint sensor 111 that senses a fingerprint of a user. The falsification determining unit 140 can obtain the input fingerprint image 115 in which the user's fingerprint is displayed through the fingerprint sensor 111. [ The user's fingerprint image 115 can be acquired in the form of a partial image capturing a part of the user's fingerprint.

The falsification determining unit 140 recognizes the fingerprint of the user by comparing the fingerprints displayed on the fingerprint image 115 of the user (hereinafter, referred to as an 'input fingerprint') and the registered fingerprints displayed on the registered fingerprint images 121 to 123 . The registered fingerprint images 121, 122, and 123 may be stored in advance in the registered fingerprint database 120 after the fingerprint registration process. The registration fingerprint database 120 may be stored in a memory (not shown) included in the falsification determination unit 140 or may be stored in an external device (not shown) such as a server capable of communicating with the falsification determination unit 140 .

8 is a diagram for explaining a process of comparing the input fingerprint image 115 and the registered fingerprint image 123. FIG. 8, the falsification determining unit 140 may match the input fingerprint image 115 and the registered fingerprint image 123 in order to compare the input fingerprint image 115 and the registered fingerprint image 123 have. For example, the falsification determining unit 140 may adjust the size of the input fingerprint image 115 or the input fingerprint image 115 so that the common region is overlapped between the input fingerprint image 115 and the registered fingerprint image 123 ) Can be rotated and translated. The falsification determining unit 140 may calculate the similarity of the fingerprint pattern in the common region and determine the recognition result based on the calculated similarity.

If the input fingerprint image 115 senses a fake fingerprint and the fingerprint patterns between the input fingerprint image 115 and the registered fingerprint image 123 are similar to each other, there is a possibility that authentication for the counterfeit fingerprint succeeds . In order to solve such a misrecognition problem, it is necessary to determine whether the input fingerprint displayed on the input fingerprint image 115 is a counterfeit fingerprint or a real fingerprint of a person. According to one embodiment, the falsification determining unit 140 may include a fake fingerprint detecting device (not shown), and the fake fingerprint detecting device may determine whether the input fingerprint is a counterfeit fingerprint.

9 is a view for explaining a feature of a pixel of a fingerprint sensor according to an embodiment.

A fingerprint sensor that performs fingerprint sensing in accordance with a start of operation may include a feature of a capacitance included in the touch sensor. The pixels that detect the fingerprint by the start of operation can be configured with a narrower pitch than the pixels of the general touch sensor. For example, the number of pixels constituting the touch sensor may be plural. The pixels for detecting the fingerprint may be composed of a plurality of pixels, and the plurality of pixels for detecting the fingerprint may be grouped into one. A sensor grouped by a plurality of pixels can be used as a touch sensor.

A plurality of pixels for detecting fingerprints are effective because detailed data of individual pixels can be used to detect forged fingerprints. Each of the pixels for fingerprint sensing can sense an electronic signal in which the fingerprint is secured by sensing light.

The pixels for fingerprint detection may have a pitch of 200um or less. At this time, the pitch of the pixels of the touch sensor grouped by the plurality of fingerprint sensing pixels may be 2.0 mm or more.

According to one embodiment, it may be necessary to reduce the pitch of the fingerprint pixels to obtain additional resolution of the fingerprint image. When the pixels of the fingerprint sensor are reduced, a clear fingerprint image can be obtained. In addition, it is necessary to reduce the pinhole diameter of the pinhole layer to reduce the angle of view and reduce the pinhole pitch.

According to one aspect of the present invention, the present invention can provide an anti-spoofing method using a device including a fingerprint sensor, which uses a biosensor included in one side of a device to simultaneously sense a plurality of biometric information of a user Generating user security information by combining fingerprint images and oxygen saturation obtained from the biometric sensor and comparing the user security information with biometric information of a user registered in advance to determine whether the user is authentic, The sensor may be characterized by a combination of a fingerprint sensor that senses the user's fingerprint image and a PPG (Photo-plethysmography) sensor that measures oxygen saturation of the user.

It will be apparent to those skilled in the art that various modifications, additions and substitutions are possible, without departing from the spirit and scope of the invention as defined by the appended claims. Should be regarded as belonging to the above-mentioned patent claims.

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 or scope of the inventive concept as defined by the appended claims. But is not limited thereto.

In the above-described exemplary system, the methods are described on the basis of a flowchart as a series of steps or blocks, but the present invention is not limited to the order of the steps, and some steps may occur in different orders . It will also be understood by those skilled in the art that the steps shown in the flowchart are not exclusive and that other steps may be included or that one or more steps in the flowchart may be deleted without affecting the scope of the invention.

Claims (11)

A biometric sensor included in one surface of the device and sensing a plurality of biometric information of the user at the same time;
A security information generating unit for generating user security information by combining a fingerprint image acquired from the biosensor and a blood oxygen saturation of a user;
A memory for storing information on biometric information of a user registered in advance;
And a falsification determining unit for determining whether the user is authentic by comparing the user security information with biometric information of the user registered in advance,
Wherein the bio-sensor comprises a fingerprint sensor for sensing a user's fingerprint image and a photo-plethysmography (PPG) sensor for measuring oxygen saturation of the user. The method according to claim 1,
Wherein the fingerprint sensor comprises:
A light emitting unit for irradiating light of a specific frequency to the fingerprint area of the user;
A light receiving unit that senses light of a specific frequency reflected by the user's fingerprint by a sensor pixel array formed of a plurality of photodiodes and outputs an electric signal having a fingerprint image;
And a fingerprint image generating unit for generating a fingerprint image through signal processing on the electric signal,
In the PPG sensor,
A color pass filter for selectively passing light of the same color to selectively sense light having the same color and wavelength band, and a color filter for selectively transmitting light having the same color and wavelength band to a part of the photodiodes included in the light- (IR Pass Filter) for selectively passing light having the same wavelength band in the infrared region to selectively sense light having the same wavelength band, characterized in that anti-spoofing is performed through a fingerprint sensor device. 3. The method of claim 2,
The fingerprint sensor includes an optical filter (Red-IR Cut Filter) for blocking light of an infrared band or more on the remaining photodiodes except the color filters and the photodiodes on which the infrared filter is mounted, among the photodiodes of the light- A device that performs anti-spoofing through a fingerprint sensor. 3. The method of claim 2,
A differential CV amplifier for amplifying the PPG signal received through the PPG sensor;
A sample amplifier for separating the PPG signal into an IR signal and a RED signal and removing an ambient noise signal;
And a measurement unit for analyzing the amplified IR signal and the RED signal to measure the user's oxygen saturation. 3. The method of claim 2,
The light-
Wherein the device comprises at least one of an internal light source located in a display panel of the device and emitting light, or an external light source positioned in a display cover glass of the device to emit light, Device. The method according to claim 1,
The biosensor includes:
And a touch sensor grouped into a plurality of fingerprint sensor pixels,
The forgery determination unit,
Wherein the user security information generated by the data obtained in each of the plurality of fingerprint sensor pixels is used for authenticity determination of the user. The method according to claim 1,
The forgery determination unit,
Comparing the fingerprint image of the user with a previously registered fingerprint image to derive a first falsification judgment value to determine whether the coincidence rate of the fingerprint pattern is higher than a predetermined reference,
Comparing a blood oxygen saturation of the user with a previously stored blood oxygen saturation to derive a second falsification judgment value to determine whether the error value corresponds to a predetermined reference value,
Wherein the authenticity determination unit determines the authenticity of the user using the first falsification judgment value and the second falsification judgment value. The method according to claim 1,
A fingerprint image quality evaluation unit for dividing the fingerprint image of the user into blocks and determining an image quality evaluation value;
A filtering unit for filtering the fingerprint image of the user to obtain a filtered fingerprint image;
A fingerprint comparator for comparing the filtered fingerprint image with a previously registered fingerprint image to determine a similarity value;
And a fingerprint authenticity determining unit that determines whether the fingerprint of the user is falsified based on the determined image quality evaluation value and the similarity value. 3. The method of claim 2,
Further comprising a pinhole layer positioned between the display panel and the biometric sensor of the device and including a plurality of pinholes for focusing to transmit light reflected by the user's fingerprint to the biosensor,
Wherein the plurality of pinholes are arranged to correspond one-to-one with a plurality of biometric sensor pixels included in the biosensor. The method according to claim 1,
A finger recognition sensor for sensing a finger of a user when the fingerprint is in contact with the biosensor;
Further comprising a real user determination circuit for determining whether the obtained fingerprint image is a fingerprint of the user's actual finger. Sensing a plurality of biometric information of a user at the same time using a biometric sensor included in one surface of the device;
Generating user security information by combining fingerprint images obtained from the biometric sensor and blood oxygen saturation of the user;
And comparing the user security information with biometric information of a user registered in advance to determine whether the user is authentic,
Wherein the biosensor is a fingerprint sensor that senses a fingerprint image of a user and a PPG (Photo-plethysmography) sensor that measures oxygen saturation of the user.

Images