KR20170077993A - Method for Certificating Fingerprint of Real Living Body by using Heart Rate - Google Patents

Abstract

The present invention relates to a method of authenticating a biometric fingerprint using a heart rate, and a method of authenticating a biometric fingerprint using a heart rate according to the present invention includes a fingerprint sensor that senses a fingerprint based on skin contact and a heart rate sensor The method comprising the steps of sensing the effective heart rate of the inside of the body of the body part in contact with the sensor module via the heartbeat sensor when the body part is in contact with the sensor module, The effective heart rate of the inside of the body contacting the sensor module through the heartbeat sensor until the completion of the matching authentication process of the fingerprint recognition or the fingerprint pattern through the fingerprint sensor during the effective heart rate sensing is continuously A second step of authenticating whether or not the effective heart rate is sensed; And a third step of applying a matching authentication result of the background pattern group.

Description

[0001] The present invention relates to a method of authenticating a fingerprint using a heart rate,

The present invention relates to a device having a sensor module including a fingerprint sensor for sensing fingerprints based on skin contact and a heartbeat sensor capable of sensing the heart rate of the skin during fingerprint sensing, And when the effective heart rate is continuously sensed through the heartbeat sensor, the fingerprint pattern for the body part is recognized or authenticated to authenticate the living body fingerprint pattern.

Ridges of the fingerprint are formed along the positions of the sweat glands in fingers or toes of the body parts of the human body, and valleys are formed between ridges and ridges. That is, the ridge of the fingerprint is a ridge of the skin along the sweat glands formed on the finger or the toe. Therefore, sweat pores that sweat the sweat glands are formed on the ridge of the fingerprint.

These fingerprints are different even if they are identical twins, and can be an identification means that can uniquely identify a specific person. In the past, such a fingerprint was used as an authentication means instead of an identification means for identifying a specific person. That is, in the conventional fingerprint authentication, after identifying a person to be authenticated by using a separate medium or an ID, the fingerprint is authenticated to authenticate the person. Therefore, attempts to steal others by forging fingerprints are continuing.

However, forgery and falsification of fingerprints is relatively easy. When fingerprint recognition is attempted by simulating fingerprints through materials having physical, chemical, and electrical characteristics similar to the epidermis of a human body, the conventional fingerprint recognition technology has a very difficult problem to exclude such simulated fingerprints. For example, when fingerprints are simulated using Gummi, which is very similar to the skin composition of the human body, it is very difficult to exclude such simulated fingerprints through conventional fingerprint recognition technology.

On the other hand, a technology for a blood flow detecting device capable of being coupled to a fingerprint sensor (Patent Registration No. 10-1123179) has been proposed. This is because it is difficult to miniaturize a vein image detection technique using a laser beam type infrared ray photometer which is conventionally used for medical use and it is difficult to miniaturize it. Since infrared rays can transmit opaque or semitransparent material in the visible ray region, Which is difficult to block.

An object of the present invention to overcome the above problems is to provide a device having a sensor module in which a fingerprint sensor that senses a fingerprint based on skin contact and a heartbeat sensor that can sense a heart rate of the inner side of the skin during fingerprint sensing are combined, When the body part of the living body of the living body is contacted with the sensor module, the living body fingerprint pattern is recognized or authenticated by authenticating that the effective heart rate is continuously sensed through the heartbeat sensor during recognition or authentication of the fingerprint pattern for the body part Or a real fingerprint authentication method using a heart rate to authenticate a living fingerprint pattern of living body by controlling the fingerprint pattern of the body part to be recognized or authenticated when the effective heart rate is continuously sensed through the heart rate sensor .

An actual biometric fingerprint authentication method using a heart rate according to the present invention includes a sensor module including a fingerprint sensor for sensing a fingerprint based on skin contact and a heart rate sensor capable of sensing a heart rate inside the skin during the fingerprint sensing The method of claim 1, further comprising the steps of: sensing an effective heart rate of the skin inside the body contacting the sensor module via the heartbeat sensor when the body part is in contact with the sensor module; A second step of authenticating that the effective heart rate of the inside of the skin of the body part in contact with the sensor module is continuously sensed through the heartbeat sensor until completion of the fingerprint recognition or fingerprint pattern matching authentication process; And applying a result to the matching authentication result of the fingerprint pattern.

According to the present invention, the actual biometric fingerprint authentication method may further include checking whether a specified body part contacts a heart rate sensor coupled to the sensor module.

According to the present invention, the actual biometric fingerprint authentication method further includes a step of activating a heart rate sensing function of the heart rate sensor when the body part is contacted with the sensor module to start heart rate sensing inside the skin in contact with the sensor module can do.

According to the present invention, the first step may include sensing a heart rate of the inside of the skin of the body part in contact with the sensor module through the heart rate sensor, reading the sensed heart rate, Lt; RTI ID = 0.0 > continuously < / RTI >

According to the present invention, the heartbeat sensor may include an optical heartbeat sensor that outputs and senses an optical signal in a wavelength range of visible light to a body part in contact with the sensor module. The optical heartbeat sensor is capable of outputting optical signals of N (N > = 2) different wavelengths of visible light, and the first step includes outputting an n < th > And determining an effective heart rate inside the skin in contact with the sensor module. Meanwhile, the optical heartbeat sensor is capable of outputting optical signals of N (N > = 2) different visible light wavelength regions, and the first step is to change the N different visible light wavelength regions into a designated pattern, And sensing an effective heart rate inside the skin in contact with the sensor module.

According to the present invention, the heartbeat sensor may include an electrocardiographic heartbeat sensor that senses a potential difference related to heartbeat through at least one electrode coupled to the sensor module. Meanwhile, the electrocardiographic heart rate sensor may include a bipolar electrocardiographic heart rate sensor or a unipolar induced electrocardiographic heart rate sensor.

According to the present invention, the heartbeat sensor includes an optical heartbeat sensor for outputting and sensing an optical signal having a wavelength specified in a body part in contact with the sensor module, and at least one electrode coupled to the sensor module for sensing a potential difference related to heartbeat And a heart rate sensor coupled to the heart rate sensor.

According to the present invention, a sensor module for recognizing a fingerprint is combined with a heartbeat sensor (for example, an optical heartbeat sensor using a visible light wavelength range, an electrocardiographic heartbeat sensor, or a heartbeat sensor of at least one of multiple heartbeat sensors) It is advantageous to authenticate whether the valid heartbeat is continuously sensed through the heartbeat sensor during the procedure so that the fingerprint pattern authenticated through the fingerprint recognition is a fingerprint pattern that recognizes the fingerprint formed in the user's body.

According to the present invention, there is an advantage in that identification and authentication are simultaneously provided through a single fingerprint by using fingerprint matching as identification means for identifying a user and using the heart rate as authentication means for authenticating fingerprints of an actual user.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a functional block diagram of an apparatus for authenticating a fingerprint of a living body using a skin heart rate according to an embodiment of the present invention. FIG.
2 is a diagram illustrating an actual biometric fingerprint authentication process according to an embodiment of the present invention.
3 is a view illustrating an actual biometric fingerprint authentication process according to another embodiment of the present invention.

The operation principle of the preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings and description. It should be understood, however, that the drawings and the following detailed description are exemplary and explanatory and are intended to provide further explanation of the invention, and are not to be construed as limiting the present invention.

In other words, the following embodiments correspond to the preferred embodiment of the preferred embodiment of the present invention. In the following embodiments, a specific configuration (or step) is omitted, or a specific configuration (or step) (Or steps), or an embodiment that incorporates functions implemented in more than one configuration (or step) into any one configuration (or step), a particular configuration (or step) It will be apparent that the present invention is not limited to the embodiments described below.

In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. The terms used below are defined in consideration of the functions of the present invention, which may vary depending on the user, intention or custom of the operator. Therefore, the definition should be based on the contents throughout the present invention.

As a result, the technical idea of the present invention is determined by the claims, and the following embodiments are merely means for effectively explaining the technical idea of the present invention to a person having ordinary skill in the art to which the present invention belongs Only.

FIG. 1 is a diagram showing a functional configuration of an apparatus 100 for authenticating a fingerprint of an actual living body using a skin heart rate according to an embodiment of the present invention.

1 is a block diagram of a device having a sensor module 105 in which a fingerprint sensor 110 for sensing a fingerprint based on skin contact and a heartbeat sensor 115 capable of sensing a heart rate inside the skin during the fingerprint sensing are combined When the user's body part is in contact with the sensor module 105 at the user's body 100, whether the effective heart rate is continuously sensed through the heartbeat sensor 115 during recognition or authentication of the fingerprint pattern for the body part The controller 110 controls the living body fingerprint pattern to be authenticated or the fingerprint pattern of the body part is recognized or authenticated when the effective heart rate is continuously sensed through the heartbeat sensor 115, It is to be understood that the functional arrangement of the apparatus 100 for authenticating a pattern is illustrated and described in the context of the present invention, , It will be appreciated that various implementations of the device 100 (e.g., some of the components may be omitted, or subdivided, or combined) may be referred to and / or modified by reference to FIG. 1, And all the methods to be inferred. The technical features of the present invention are not limited only by the method shown in FIG.

The device 100 of the present invention is a general term for a configuration for recognizing and authenticating a fingerprint of a user's body part, and includes a variety of device types, modules (or chips) mounted on various devices, a distributed system And can be implemented in various forms.

According to a first embodiment of the present invention, the device 100 may be implemented in the form of various devices used by a user. For example, the device 100 may be implemented in the form of a terminal (e.g., a smart phone, a mobile phone, a tablet PC, a notebook PC, etc.), a recognition device, an authentication device, a door lock device, 1 may be implemented in the form of H / W, S / W, or a combination thereof mounted on each device.

According to a second embodiment of the present invention, the device 100 may be implemented in the form of a module (or chip) mounted on various devices used by the user. For example, the device 100 may be implemented in the form of a module (or chip) embedded in various devices such as a terminal, a recognition device, an authentication device, a door lock device, etc. used by a user, The configuration unit may be implemented in a form of H / W or S / W or a combination thereof mounted on the module (or chip), and in accordance with an implementation method, a part of the functional components shown in FIG. And the other part may be implemented on the device side on which the module (or chip) is mounted.

According to the third embodiment of the present invention, the apparatus 100 can be implemented in a distributed manner through a server on the network and various devices used by the user. For example, the device 100 may include various devices such as a terminal, a recognition device, an authentication device, a door lock device, and the like, used by a user, and a server on a network. And other parts may be implemented in a server on the network.

According to the fourth embodiment of the present invention, the apparatus 100 may be implemented in a form of partially combining two or more embodiments among the first to third embodiments. That is, the present invention is not limited to the method of implementing the device 100 or the embodiment, and it is evident that the present invention belongs to the scope of the present invention if the functions included in the claims are implemented in any form of function.

The device 100 of the present invention includes a fingerprint sensor 110 for sensing a fingerprint based on skin contact in a hardware manner and a heartbeat sensor capable of sensing the heart rate of the skin during fingerprint sensing using the fingerprint sensor 110 And a sensor module 105, to which the sensor module 115 is coupled. Preferably, the sensor module 105 has a contact that physically contacts or is proximate to the user's skin to sense fingerprints based on skin contact.

The fingerprint sensor 110 may be any sensor capable of recognizing a fingerprint, such as an electrostatic sensor, an optical sensor, and an ultrasonic sensor. If the sensor is capable of sensing fingerprints of any sensors that are proposed or improved as well as existing sensors It is clear that the sensor module 105 of the present invention is available and belongs to the scope of the right. Hereinafter, the features of the present invention will be described with reference to an embodiment using the electrostatic fingerprint sensor 110 for sensing a capacitance. However, it should be clear that embodiments of the present invention are by no means limited to the manner in which electrostatic sensors are used.

The heartbeat sensor 115 is a sensor capable of sensing the heart rate of the inside of the body part when the body part of the user touches the contact part of the sensor module 105. The heartbeat sensor 115 preferably optically detects the heart rate using an optical signal in the visible light wavelength range An optical heart rate sensor 115 for sensing the heart rate, and an electrocardiographic heart rate sensor 115 for sensing the heart rate in the electrocardiogram system.

According to the first heartbeat sensor 115 of the present invention, the heartbeat sensor 115 may include an optical heartbeat sensor (not shown) for outputting and sensing an optical signal in a wavelength range of visible light to a body part in contact with the sensor module 105 115 may include an optical heart rate sensor 115. When an optical signal of the wavelength designated by the human body is output, part of the optical signal penetrates into the inside of the skin. Generally, in the case of a blood flow detecting sensor made for medical use, an optical signal of an infrared ray region in the form of a laser beam is outputted. In this case, a vein image can be sensed by penetrating deeply into the skin and reflecting infrared rays in the blood. , It is difficult to miniaturize the sensor size. The present invention relates to a small sensor module 105 mounted on a smart phone or the like using an optical signal that penetrates an optical signal of a visible light wavelength belonging to a green light wavelength range or a red light wavelength range, which can be generated using an LED or the like, Thereby implementing a combinable optical heart rate sensor 115. According to the present invention, blood red blood cells have a characteristic of reflecting an optical signal even in a red light wavelength range of a visible light ray without using an infrared wavelength range, and conversely, they have a characteristic of absorbing an optical signal in a green light wavelength range. Therefore, when a specific wavelength region on the red light wavelength region and the green light wavelength region of the visible light ray are used, the erythrocytes in the blood have a predictable absorption rate and reflectance. In the present invention, the optical signal of the optical heartbeat sensor 115 It is possible to minimize the size and control the visible light wavelength region, thereby sensing the heart rate while blocking the forgery fingerprint.

According to an example of the optical heartbeat sensor 115 according to the first heartbeat sensor 115, the optical heartbeat sensor 115 may detect a specific wavelength region (for example, green light The device 100 outputs the optical signal of the specific wavelength range and outputs the optical signal of the specific wavelength range to the sensor module 100 through the ratio of the absorption rate and the reflectance corresponding to the specific wavelength range, 105) of the skin can be sensed.

According to another example of the optical heartbeat sensor 115 according to the second heartbeat sensor 115, the optical heartbeat sensor 115 includes N (N > = 2) different visible light wavelength regions (N wavelength regions in which a wavelength region to a red light wavelength region is divided), and the apparatus 100 is capable of outputting an optical signal for sensing a heart rate among the N different wavelengths of visible light, N) wavelengths and sense the heart rate inside the skin in contact with the sensor module 105.

According to another example of the optical heartbeat sensor 115 according to the second heartbeat sensor 115, the optical heartbeat sensor 115 may include N (N? 2) different visible light wavelength regions (e.g., (N) wavelength regions in which the green light wavelength region to the red light wavelength region are divided), and the apparatus 100 is capable of outputting optical signals of the N different visible light wavelength regions, 105) in the skin can be sensed.

According to the first heartbeat sensor 115, when the counterfeit fingerprint is made of an opaque material, the optical heartbeat sensor 115 can not sense the heartbeat inside the skin. When the counterfeit fingerprint is made of a translucent material, Sensing the inner heart rate is not continuously sensed even if it is difficult or even sensed. Therefore, the optical heartbeat sensor 115 according to the first heartbeat sensor 115 can block the counterfeit fingerprints of the opaque material or the translucent material.

According to an embodiment of the second heartbeat sensor 115 of the present invention, the heartbeat sensor 115 includes an electrocardiographic heartbeat sensor 115 for sensing a potential difference associated with heartbeat through at least one electrode coupled to the sensor module 105 ). Electrocardiographic heart rate sensor 115 is a sensor that measures cardiac electrical signals indicative of changes in heart rate-related potentials, including depolarization of the myocardium (e.g., contraction of the heart muscle in response to electrical stimulation) and repolarization ≪ / RTI > relaxation of the heart muscle that occurs when it exits the cell). The electrical activity of the heart is produced by cardiac cells when ions exchange across cell membranes.

According to an example of the electrocardiographic heartbeat sensor 115 according to the second heartbeat sensor 115, the electrocardiographic heartbeat sensor 115 may include a bipolar electrocardiographic heartbeat sensor 115. The bipolar-induced electrocardiographic heart rate sensor 115 is a sensor for sensing a very small potential difference between two points, and at least two electrodes are required to sense the heart rate. Preferably, the circuit between the at least two electrodes is via the heart desirable. For example, one electrode of the bipolar electrocardiographic heart rate sensor 115 is in contact with the left body part (e.g., the left hand, the left hand drum, etc.) of the human body based on the heart position of the human body, (E.g., a right hand, a right finger, and the like). For example, when the device 100 is implemented in the form of a smartphone, when a finger holding the smartphone with the left hand touches the contact portion of the sensor module 105, the left- The condition of the bipolar electrocardiographic heartbeat sensor 115 can be satisfied if one electrode of the heartbeat sensor 115 is formed and another electrode is formed at the contact portion of the sensor module 105.

According to another example of the electrocardiographic heart rate sensor 115 according to the second heart rate sensor 115, the electrocardiographic heart rate sensor 115 may include a unipolar induced electrocardiographic heart rate sensor 115. The unipolar induced electrocardiographic heartbeat sensor 115 is a sensor for recording an electrocardiogram using one electrode, and it is possible to sense a heart rate even with one electrode. In this case, the electrode for sensing the heart rate may be formed in the contact portion of the sensor module 105 or in the form of an electrode portion coupled to the sensor module 105.

According to the second heartbeat sensor 115, the electrocardiographic heartbeat sensor 115 can sense a very small potential difference caused by a heartbeat only when an electrode contacts the body part directly. If a counterfeit fingerprint is made in contact with a body part, a minute electric potential difference can not be sensed unless it is made of a material (for example, a metal material such as gold, silver or copper) having little electrical resistance. However, if the fingerprint sensor 110 is an electrostatic sensor, the capacitance corresponding to the skin surface can not be measured through the counterfeit fingerprint made of a material having little electrical resistance. Therefore, the electrocardiographic heartbeat sensor 115 according to the second heartbeat sensor 115 can not perform the fingerprint sensing of a material having almost no electrical resistance, Fingerprints can block the counterfeit fingerprint because sensing the heart rate is impossible (or difficult).

According to the third heartbeat sensor 115 of the present invention, the heartbeat sensor 115 includes an optical heartbeat sensor 115 for outputting and sensing an optical signal of a specified wavelength to a body part in contact with the sensor module 105, And an electrocardiographic heartbeat sensor 115 for sensing a potential difference associated with the heartbeat through at least one electrode coupled to the sensor module 105.

According to the third heartbeat sensor 115, the compound heartbeat sensor 115 can block all the counterfeit fingerprints except the counterfeit fingerprints made of a material which is completely transparent and has little electrical resistance. However, it is virtually impossible to fabricate a counterfeit fingerprint that is transparent and has little electrical resistance. A method of increasing the electrical conductivity of a highly ductile material capable of forgery of fingerprints (for example, a material similar to the ductility of skin) is produced by mixing carbon powder or metal powder. The carbon powder or metal powder is mixed with a soft material It becomes not only opaque but also increases the hardness of the material, making it impossible to use it as a counterfeit fingerprint. Even if you develop a material that solves this problem in the distant future, using an electrostatic sensor that senses fingerprints electrostatically can not provide fingerprint sensing with a counterfeit fingerprint made from a material that has little electrical resistance. Therefore, the composite heartbeat sensor 115 according to the third heartbeat sensor 115 can block all the counterfeit fingerprints except the living human being (= heartbeat).

Referring to FIG. 1, the apparatus 100 includes a contact confirmation unit 120 for confirming whether a body part capable of sensing a heart rate is in contact with a heartbeat sensor 115 coupled to the swing module, 105 to activate the heart rate sensing function of the heart rate sensor 115 and to start heart rate sensing inside the skin in contact with the sensor module 105. [

In order to recognize or authenticate the fingerprint through the fingerprint sensor 110 of the sensor module 105, the user must perform an action of approaching or contacting the contact part of the sensor module 105 with the user's designated body part. 120 in cooperation with the sensor module 105 confirms that the body part contacts the heartbeat sensor 115 coupled to the swing module. For example, the contact confirmation unit 120 confirms whether the user's designated body part can be sensed (for example, by detecting capacitance change) through the fingerprint sensor 110 of the sensor module 105, And the heartbeat sensor 115 coupled to the sensor module 105 can be checked. Alternatively, the contact confirmation unit 120 may detect a change in sensing value of the heartbeat sensor 115 (for example, a light amount change sensed through the optical heartbeat sensor 115 or a potential difference change sensed through the electrocardiographic heartbeat sensor 115) Etc.), it is possible to confirm whether or not the body part is in contact with the heartbeat sensor 115 coupled with the sensor module 105.

According to the method of the present invention, the activity control unit 125 normally keeps the heart rate sensing function of the heart rate sensor 115 in an inactive state and controls the heart rate sensor 115 via the contact determination unit 120 The activation control unit 125 activates the heart rate sensing function of the heart rate sensor 115 to start heart rate sensing inside the skin in contact with the sensor module 105. [ Thus, the apparatus 100 minimizes the waste of power and minimizes errors in heart rate sensing for noise. However, the present invention is not limited to selectively activating / deactivating the heart rate sensor.

1, the device 100 uses a fingerprint sensor 110 of the sensor module 105 to sense a user's body part in contact with or approaching the sensor module 105 in a contact manner, A fingerprint recognition unit 135 for generating a fingerprint pattern (for example, a feature point on a ridge pattern) of the body part using the sensed sensing data; A fingerprint storage unit 140 for generating a corresponding fingerprint template and storing the corresponding fingerprint template in a designated storage area, and a fingerprint matching unit 145 for authenticating the generated fingerprint pattern using a user's fingerprint template stored in a designated storage area do.

When a user's designated body part contacts or approaches the sensor module 105 and / or when the body part is in contact with the sensor module 105 and the heart rate is sensed through the heart rate sensor 115, and / or When the effective heart rate is sensed through the heartbeat sensor 115, the sensing processor 130 senses the body part in contact with the sensor module 105 through the fingerprint sensor 110, And processing is performed so as to obtain sensing data according to the sensing method. According to an embodiment of the present invention, the sensing processing unit 130 may selectively obtain the sensing data under the control of the authentication control unit 160 described below.

When the sensing data sensed from the fingerprint sensor 110 is obtained through the sensing processing unit 130, the fingerprint recognition unit 135 recognizes the sensing data in accordance with a fingerprint recognition algorithm corresponding to the sensing method of the fingerprint sensor 110, And performs a process of correcting the sensing data obtained through the processing unit 130 so as to be preprocessable. Preferably, the fingerprint recognition unit 135 performs a smoothing process on the sensing data obtained through the sensing unit 130, and the noise in the sensing process is removed through the smoothing process.

The fingerprint recognition unit 135 performs a preprocessing procedure for reading the corrected sensing data obtained through the sensing processing unit 130. [ Preferably, the fingerprint recognition unit 135 performs a binarization process, a thinning process, and a directionality extraction process on the acquired / corrected sensing data. The binarization procedure includes a procedure for distinguishing between a ridge portion and a valley portion on the sensing data in black and white. The thinning procedure includes a process of distinguishing the width of the ridge on the binarized sensing data by a line of a specified reference pixel (e.g., one pixel). The directional extraction procedure includes a procedure of extracting a relative direction of a ridge (e.g., a thin line) within the entire area of the binarized or thinned sensing data.

The fingerprint recognition unit 135 reads the preprocessed sensing data and performs a procedure of generating a fingerprint pattern including minutiae points on the ridge pattern included in the sensing data. Preferably, the feature point includes at least one of a start point, an end point, a branch point, a center point, and a delta, and may be a merge, a loop, a bridge, a cross, , Triangle, Break, Spur, Ladder, Double Break, Break & Merge, Iceland, and more. have. According to the embodiment of the present invention, the sensing processing unit 130 can selectively generate the fingerprint pattern under the control of the authentication control unit 160 described below.

In the case of registering a fingerprint of a user, the fingerprint storage unit 140 may generate a fingerprint template including the generated fingerprint pattern and store the fingerprint template in a designated storage area. According to an embodiment of the present invention, in order to register a fingerprint of a user, the sensor module 105 senses the same body part of the user (for example, in the process of contacting the same body part to the sensor module 105, The fingerprint storage unit 140 may generate a fingerprint template including a union of repeatedly generated fingerprint patterns through the repeated process and store the fingerprint template in a designated storage area.

On the other hand, when authenticating the user's fingerprint, the fingerprint matching unit 145 compares the fingerprint pattern of the fingerprint template stored in the designated storage area with the generated fingerprint pattern through the fingerprint recognition unit 135, And generates an authentication result of the fingerprint pattern in which the pattern is matched. According to the embodiment of the present invention, the sensing processing unit 130 can selectively process the fingerprint pattern matching authentication under the control of the authentication control unit 160 described below.

Referring to FIG. 1, the apparatus 100 includes a heartbeat sensing unit 150 sensing a heart rate of an inner part of a skin of a body part contacting the sensor module 105 through the heartbeat sensor 115, And a heartbeat authentication unit 155 for reading the heartbeat number read from the heartbeat frequency range and belonging to the human heartbeat effective range and for certifying that the continuity is continuously maintained for a predetermined time.

It is confirmed that the body part designated by the contact confirmation unit 120 is in contact with the heartbeat sensor 115 coupled to the sensor module 105 and / The heartbeat sensing unit 150 senses the heartbeat sensor 115 coupled to the sensor module 105 (for example, the heartbeat sensor 115) (At least one heartbeat sensor 115 of at least one of an optical heartbeat sensor 115, an electrocardiographic heartbeat sensor 115 and a compound heartbeat sensor 115 using a visible light wavelength range) Sensing the heart rate inside the skin of the site.

According to the method of the present invention, the heartbeat sensing unit 150 continuously senses the heartbeat in the skin while the body part is in contact with the sensor module 105, and at least the fingerprint storage unit It is preferable to continuously sense the heart rate inside the skin of the body part that has contacted the sensor module 105 until the fingerprint template has been stored through the fingerprint matching unit 140 or the fingerprint authentication is completed through the fingerprint matching unit 145 Do.

The heartbeat authentication unit 155 sets the effective range of the human heartbeat to the actual heart rate of the human body and reads the heart rate sensed through the heartbeat sensing unit 150 to determine whether the heartbeat is within a valid human heart rate range First authentication. If the heart rate sensed by the heart rate sensing unit 150 is within the human heart rate validity range, the heartbeat authentication unit 155 maintains continuity of sensing the heart rate pertaining to the human heart rate effective range for a predetermined period of time . That is, the present invention uses fingerprint matching of a fingerprint pattern as identification means for identifying a user and uses the heart rate continuously sensed during fingerprint pattern recognition or authentication as an authentication means for authenticating that the fingerprint is an actual user's fingerprint.

According to the embodiment of the present invention, the heartbeat authentication unit 155 may be configured to detect a fingerprint pattern on the inner side of the skin of the body part contacting the sensor module 105 before the procedure of generating the fingerprint pattern through the fingerprint recognition unit 135 is started. It is possible to authenticate whether the effective heart rate is sensed or not and to check whether the inside of the skin of the body part in contact with the sensor module 105 is valid until the procedure of generating and storing or authenticating the fingerprint pattern through the fingerprint recognition unit 135 is completed It is desirable to continue the process of authenticating that the heart rate is sensed.

Referring to FIG. 1, the apparatus 100 processes the fingerprint sensor 110 to sense the fingerprint of the body part through the fingerprint sensor 110 when sensing the sensed heart rate and sensing an effective heart rate, And the authentication unit 160 controls the authentication unit 160 to perform a matching authentication process of the fingerprint patterns sensed through the fingerprint authentication unit 160. The fingerprint authentication unit 155 performs authentication of the fingerprint pattern And authenticates whether the effective heart rate is continuously sensed through the heartbeat sensor 115 until the completion of the authentication procedure. Meanwhile, the apparatus 100 further includes an authentication result processing unit 165 for applying the result of the continuous sensing of the effective heart rate to the matching authentication result of the fingerprint pattern.

When the heart rate sensed by the heart rate sensing unit 150 is an effective heart rate, the authentication control unit 160 controls the sensing unit 130 to sense the fingerprint of the body part to acquire sensing data, Or controls to generate a fingerprint pattern corresponding to the sensing data through the fingerprint recognition unit 135 and / or controls the fingerprint template including the fingerprint pattern to be stored through the fingerprint storage unit 140 And / or the fingerprint matching unit 145 to perform a matching authentication process for the fingerprint pattern.

Meanwhile, the heartbeat authentication unit 155 may control the fingerprint recognition or authentication control through the authentication control unit 160 (for example, sensing the fingerprint of the body part through the sensing processing unit 130 to obtain sensing data, And / or control to generate a fingerprint pattern corresponding to the sensed data through the fingerprint recognition unit 135 and / or to control the fingerprint template including the fingerprint pattern to be stored through the fingerprint storage unit 140 Or controlling the fingerprint matching unit 145 to perform a matching authentication process on the fingerprint pattern through the fingerprint matching unit 145 and / or the fingerprint matching unit 145) Verify that the effective heart rate is continuously sensed. If the effective heart rate is not sensed through the heartbeat sensor 115 at least once during the fingerprint recognition or authentication control, the heartbeat authentication unit 155 generates a heartbeat authentication error, .

The heartbeat authentication unit 155 generates a heartbeat authentication result regarding whether the effective heartbeat is continuously sensed through the heartbeat sensor 115 during the fingerprint recognition or authentication control.

The authentication result processing unit 165 confirms the fingerprint pattern authentication result of the fingerprint pattern authentication procedure performed through the fingerprint matching unit 145 and the heartbeat authentication result generated through the heartbeat authentication unit 155, And combines the fingerprint pattern authentication result and the cardiac authentication result to generate an actual biometric fingerprint authentication result. If authentication of the fingerprint pattern is successfully performed through the fingerprint matching unit 145 and the heartbeat authentication unit 155 has succeeded in the heartbeat authentication, the authentication result processing unit 165 obtains the fingerprint Generates an actual biometric fingerprint authentication result that determines that the authentication is successful, and otherwise generates an actual biometric fingerprint authentication result corresponding to the authentication failure. The authentication result processing unit 165 processes the generated biometric fingerprint authentication result through the designated output means.

According to the embodiment of the present invention, when the effective heart rate is continuously sensed until the completion of the matching authentication procedure, the authentication result processing unit 165 cites the matching authentication result of the fingerprint pattern as it is, The authentication failure is determined irrespective of the matching authentication result of the fingerprint pattern when the effective heart rate is not continuously sensed even once (for example, for a specified unit time) until the time point.

2 is a diagram illustrating an actual biometric fingerprint authentication process according to an embodiment of the present invention.

2 is a block diagram of a device having a sensor module 105 in which a fingerprint sensor 110 for sensing fingerprints based on skin contact and a heartbeat sensor 115 capable of sensing the heart rate inside the skin during the fingerprint sensing are combined When the user's body part is in contact with the sensor module 105 at the user's body 100, whether the effective heart rate is continuously sensed through the heartbeat sensor 115 during recognition or authentication of the fingerprint pattern for the body part A user may be a person who is familiar with the technique of the present invention. Referring to FIG. 2 and / or modified by the person skilled in the art, It is possible to deduce an implementation method (for example, an implementation method in which some steps are omitted or the order is changed), but the present invention is not limited to the above- And the technical features thereof are not limited only by the method shown in FIG.

Referring to FIG. 2, the apparatus 100 of the present invention checks whether a body part contacts a contact part of the sensor module 105 (200). If it is determined that the body part contacts the contact part of the sensor module 105, the device 100 can activate the heartbeat sensor 115 coupled to the sensor module 105 (step 205). The activation of the heartbeat sensor 115 may be omitted if the heartbeat sensor 115 is activated.

The device 100 includes a heart rate sensor 115 coupled to the sensor module 105 (e.g., an optical heart rate sensor 115 using an optical wavelength range, an electrocardiographic heart rate sensor 115, a complex heart rate sensor 115, (At least one heartbeat sensor 115) to sense the heart rate of the inner part of the skin of the body part in contact with the sensor module 105 (step 210).

If the heart rate of the inside of the skin of the body part in contact with the sensor module 105 is sensed, the device 100 can detect the body part in contact with the contact part of the sensor module 105 with the sensing method of the fingerprint sensor 110 And the sensed data is obtained (215). According to an embodiment of the present invention, the apparatus 100 may acquire the sensed data when the effective heart rate is sensed through the heart rate sensor 115 (215).

When the sensing data is obtained through the fingerprint sensor 110 of the sensor module 105, the device 100 reads the sensing data according to a fingerprint recognition algorithm corresponding to the sensing method of the fingerprint sensor 110, A fingerprint pattern including minutiae points on the ridge pattern included in the sensing data is generated (220).

If the fingerprint is registered, the device 100 generates a fingerprint template corresponding to the generated fingerprint pattern and stores the fingerprint template in the designated storage area (225). If the fingerprint is authenticated, the device 100 compares the fingerprint pattern of the fingerprint temple stored in the designated storage area with the generated fingerprint pattern to perform a matching check (230), and then the fingerprint pattern matching And generates an authentication result of the fingerprint pattern that has been confirmed (235).

Meanwhile, when the heart rate of the body part in contact with the sensor module 105 is sensed, the device 100 reads the sensed heart rate and authenticates whether it is within a human heart rate valid range measurable by a living body, (240) whether the effective heart rate is sensed through the heartbeat sensor (115) by authenticating whether the heartbeat in the human heartbeat effective range is continuously maintained for a predetermined period of time.

If a valid heartbeat is not sensed through the heartbeat sensor 115, the device 100 recognizes and authenticates a fingerprint pattern using a fingerprint sensor. The authentication result corresponding to the failure of the biometric fingerprint authentication may be generated and output 260 regardless of the authentication result of the fingerprint pattern.

Meanwhile, when it is confirmed that the effective heart rate is sensed through the heartbeat sensor 115, the device 100 recognizes the fingerprint pattern through the fingerprint sensor 110 and stores the fingerprint pattern or processes the fingerprint pattern matching authentication (245), it is checked whether the effective heart rate is continuously sensed through the heart rate sensor (115).

If a process for recognizing a fingerprint pattern through the fingerprint sensor 110 and storing a fingerprint pattern or processing for matching authentication of a fingerprint pattern is being performed and the effective heart rate is not continuously sensed through the heart rate sensor 115, The authentication unit 100 can generate and output an authentication result corresponding to the failure of the actual biometric fingerprint authentication regardless of the authentication process of recognizing and authenticating the fingerprint pattern or the authentication result of the fingerprint pattern.

Meanwhile, when the fingerprint pattern matching authentication procedure is completed (250) while the effective heart rate is continuously sensed through the heartbeat sensor 115, the device 100 determines whether the fingerprint sensor is continuously sensed through the heartbeat sensor 115 A cardiac authentication result for the heart rate is generated (255), and an actual biometric fingerprint authentication result is generated by combining the authentication result of the fingerprint pattern and the cardiac authentication result (260). Preferably, when the fingerprint pattern matching authentication is successful and the heartbeat authentication is successful, the device 100 generates and outputs an actual biometric fingerprint authentication result that determines that the fingerprint recognized in the actual living body is an authentication success (260) If not, an actual biometric fingerprint authentication result corresponding to the authentication failure is generated and output (260).

FIG. 3 is a view showing an actual biometric fingerprint authentication process according to another embodiment of the present invention.

3 is a block diagram of a device having a sensor module 105 in which a fingerprint sensor 110 for sensing a fingerprint based on skin contact and a heartbeat sensor 115 capable of sensing the heart rate of the inside of the skin during the fingerprint sensing are combined When the user's body part is in contact with the sensor module 105 at the user's body 100, when the effective heart rate is continuously sensed through the heartbeat sensor 115, control is performed to recognize or authenticate the fingerprint pattern of the body part The user can be authenticated with a living body fingerprint pattern by referring to and / or modifying the body fingerprint authentication process in the living body, It will be appreciated that the method of practice (e.g., a method in which some steps are omitted or the order is changed) may be inferred, And the technical features thereof are not limited only by the method shown in FIG.

Referring to FIG. 3, the apparatus 100 of the present invention checks whether a body part contacts a contact portion of the sensor module 105 (300). If it is confirmed that the body part contacts the contact part of the sensor module 105, the device 100 can activate the heartbeat sensor 115 coupled to the sensor module 105 (step 305). The activation of the heartbeat sensor 115 may be omitted if the heartbeat sensor 115 is activated.

The device 100 includes a heart rate sensor 115 coupled to the sensor module 105 (e.g., an optical heart rate sensor 115 using an optical wavelength range, an electrocardiographic heart rate sensor 115, a complex heart rate sensor 115, (At least one heartbeat sensor 115), the heart rate of the inner part of the skin of the body contacting the sensor module 105 is sensed (310).

If the heart rate of the body part in contact with the sensor module 105 is sensed, the device 100 reads the sensed heart rate and authenticates whether it is within the human heart rate valid range measurable by the living body, (315) whether the effective heart rate is sensed through the heartbeat sensor 115 by authenticating whether the heartbeat of the human heartbeat valid range is continuously maintained for a predetermined period of time.

If it is confirmed that the effective heart rate is sensed through the heartbeat sensor 115, the device 100 recognizes the fingerprint pattern through the fingerprint sensor 110 and stores the fingerprint pattern or processes the fingerprint pattern matching authentication (320). ≪ / RTI >

The device 100 processes the body part in contact with the contact part of the sensor module 105 in accordance with the sensing method of the fingerprint sensor 110 when the effective heart rate is sensed through the heartbeat sensor 115, And acquires one sensed data (325).

When the sensing data is acquired through the fingerprint sensor 110 of the sensor module 105 and the effective heart rate is sensed through the heartbeat sensor 115, The sensing data is read according to a corresponding fingerprint recognition algorithm to generate a fingerprint pattern including the minutiae on the ridge pattern included in the sensed data (330).

If the fingerprint is registered, the device 100 generates a fingerprint template corresponding to the generated fingerprint pattern and stores the generated fingerprint template in the designated storage area (335) when the effective heart rate is sensed through the heart rate sensor 115, . On the other hand, if the fingerprint is authenticated, the device 100 compares the generated fingerprint pattern with the fingerprint pattern of the fingerprint temple stored in the designated storage area when the effective heart rate is sensed through the heart rate sensor 115, and confirms the matching After the procedure is performed (340), an authentication result of the fingerprint pattern in which the fingerprint pattern is matched is generated (345).

Meanwhile, the apparatus 100 recognizes the fingerprint pattern through the fingerprint sensor 110 and controls the heartbeat sensor 115 to perform a process of storing a fingerprint pattern or performing a process of matching authentication of a fingerprint pattern (320) If the fingerprint sensor 110 recognizes the fingerprint pattern and stores the fingerprint pattern or controls the process of matching authentication of the fingerprint pattern, the heartbeat sensor 115 ), The device 100 generates and outputs an authentication result corresponding to the failure of the actual biometric fingerprint authentication regardless of the authentication process of recognizing and authenticating the fingerprint pattern or the authentication result of the fingerprint pattern (360).

Meanwhile, during the control to recognize a fingerprint pattern through the fingerprint sensor 110 to store a fingerprint pattern or perform authentication processing of fingerprint pattern matching, an effective heart rate is continuously sensed through the heartbeat sensor 115, When the fingerprint pattern matching authentication procedure is completed (350), the device 100 generates a heartbeat authentication result for the continuously sensed effective heart rate through the heartbeat sensor 115 (355) The result is combined with the cardiac authentication result to generate an actual biometric fingerprint authentication result and output (360). Preferably, when the fingerprint pattern matching authentication is successful and the heartbeat authentication is successful, the device 100 generates and outputs an actual biometric fingerprint authentication result that determines that the fingerprint recognized in the actual living body has been successfully authenticated (360) If not, an actual biometric fingerprint authentication result corresponding to the authentication failure is generated and output (360).

100: Device 105: Sensor module
110: fingerprint sensor 115: heart rate sensor
120: contact confirmation unit 125: active control unit
130: sensing processing unit 135: fingerprint recognition unit
140: Fingerprint storage unit 145: Fingerprint matching unit
150: heartbeat sensing unit 155: heartbeat authentication unit
160: authentication control unit 165: authentication result processing unit

Claims (12)

A method for performing a method through an apparatus having a sensor module including a fingerprint sensor for sensing a fingerprint based on skin contact and a heartbeat sensor capable of sensing a heart rate of the skin inside the fingerprint sensing,
A first step of sensing an effective heart rate inside the skin of the body part contacting the sensor module through the heartbeat sensor when the body part is in contact with the sensor module;
And an authentication unit for authenticating whether the effective heart rate inside the skin of the body part in contact with the sensor module is continuously sensed through the heartbeat sensor until completion of the matching authentication process of fingerprint recognition or fingerprint pattern through the fingerprint sensor at the effective heart rate sensing Step 2; And
And applying a result of the continuous sensing of the effective heart rate to the matching authentication result of the fingerprint pattern.
The method according to claim 1,
Further comprising the step of confirming whether the designated body part is in contact with the heartbeat sensor coupled to the sensor module.
The method according to claim 1,
And activating a heart rate sensing function of the heart rate sensor to start heart rate sensing inside the skin in contact with the sensor module when the body part contacts the sensor module. Way.
2. The method according to claim 1,
Sensing a heart rate of the inside of the skin of the body part in contact with the sensor module through the heart rate sensor; And
And a step of reading the sensed heart rate to authenticate whether the persistence which is continuously sensed for a predetermined time belongs to a human heart rate effective range.
The method according to claim 1,
When the body part is contacted to the sensor module to sense the heart rate through the heart rate sensor,
Generating a fingerprint pattern using sensing data sensed by the fingerprint sensor;
And storing the generated fingerprint pattern or processing the matching authentication of the generated fingerprint pattern. ≪ Desc / Clms Page number 20 >
The heart rate sensor according to claim 1,
And an optical heartbeat sensor for outputting and sensing an optical signal in a wavelength region of visible light on a body part in contact with the sensor module.
The method according to claim 6,
The optical heartbeat sensor is capable of outputting optical signals of N (N? 2) different wavelengths of visible light,
The first step includes determining an nth (1? N? N) wavelength for sensing the heart rate among the N different visible light wavelengths and sensing the effective heart rate inside the skin in contact with the sensor module Wherein the fingerprint authentication method comprises the steps of:
The method according to claim 6,
The optical heartbeat sensor is capable of outputting optical signals of N (N? 2) different wavelengths of visible light,
Wherein the first step includes the step of sensing the effective heart rate inside the skin contacting the sensor module for each wavelength while changing the N different visible light wavelength regions to a designated pattern. Actual biometric fingerprint authentication method.
The heart rate sensor according to claim 1,
And an electrocardiographic heartbeat sensor for sensing a potential difference related to a heartbeat through at least one electrode coupled to the sensor module.
The electrocardiographic heart rate sensor according to claim 9,
A bipolar electrocardiographic heart rate sensor or a unipolar induced electrocardiographic heart rate sensor.
The heart rate sensor according to claim 1,
A combination of an optical heart rate sensor for outputting and sensing an optical signal of a specified wavelength to a body part in contact with the sensor module and an electrocardiograph heart rate sensor for sensing a potential difference related to heart rate through at least one electrode coupled to the sensor module And a heartbeat sensor for detecting the heartbeat.
2. The method according to claim 1,
Wherein when the effective heart rate is continuously sensed until the completion of the matching authentication procedure, the matching authentication result of the fingerprint pattern is used as it is. If the effective heart rate is not continuously sensed until the completion of the matching authentication procedure, And determining an authentication failure regardless of the authentication result.

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