JP2010134965A - Authentication device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To allow lasting biometric authentication without a risk of fabrication, etc. <P>SOLUTION: Light which is made incident on a vein area of a detection object at a shallow angle aslant to the epidermal surface and passes through epidermal tissues and dermal tissues aslant while being scattered is irradiated, back scattered light to be generated by passage of the light through the dermal tissues at the back of the vein area of the detection object is used as background to fetch return light including a vein pattern generated by absorption of the back scattered light by a vein of the vein area of the detection object, and the vein pattern of the return light to be fetched is collated with a vein pattern to be stored. A means for fetching the return light includes a shield plate which faces an epidermal surface part on the side where the vein area of the detection object is to the direction that the light to be irradiated passes the epidermal tissues and the dermal tissues aslant, and shields that reflected light and the scattered light to be generated until the light reaches the back of the vein area of the detection object and the scattered light after the light passes through the back of the vein area of the detection object are mixed into the return light to be emitted from the epidermal surface part. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an authentication device.

  Fingerprints, palm prints, etc., which are widely used for personal authentication, are the parts where the ridge network formed by the skin's epidermal tissue sinking into the uneven structure of the dermis can be seen directly from the outside. It reflects the deep skin structure. For the purpose of making the tactile nerve terminals distributed in the deep skin more easily detect external stimuli and physiological reasons such as the strength against friction, the skin of the palms and soles is different from the skin of other parts, such as the dermis. It has a unique skin structure in which the shape of the deep skin structure matches the shape of the epidermis. Fingerprints conventionally used for personal authentication basically use the permanence of this deep structure.

  By the way, the biometric authentication using the above-mentioned fingerprint is not necessarily sufficient for the so-called “spoofing”. For example, since fingerprints easily remain as traces on other objects and are easily visible, the risk of being counterfeited by a third party cannot be denied.

  On the other hand, for example, if biometric authentication can be performed using the skin of another part, it is considered that the risk of forgery can be avoided. However, the epidermis layer is fluid, such as all the cells changing every 28 days, and there are various changes due to rough skin, dryness, etc., so this pattern has no permanentness. Also, as a result of the measurement, the finger stem part and the thumb ball part etc. are completely different from the fingerprint of the fingertip, and the epidermis and the epidermis pattern are completely different and tend to be orthogonal, and the epidermis pattern can be used for biometric authentication. Can not.

  Unlike special cases such as fingerprints of the fingertips that can be seen by directly reflecting the deep structure directly on the epidermis, even with the same palm type, most skins of the human body, including the palm of the thumb ball, the skin of the finger stem and back of the hand, etc. In addition, the pattern of the deep structure does not match the pattern of the epidermis, and the visible light is shielded by melanin pigments such as scattering and basal cells by the six-layered epidermis, making it difficult to see from the outside. is there. For this reason, for example, when a ring-type authentication device is formed, the actual situation is that the skin pattern that contacts the inside of the ring at the time of wearing cannot be used for authentication as it is.

  On the other hand, the deep structure of the skin is basically unique to the living body, and there is almost no secular change as it is said by fingerprints. For example, the permanent structure of what is called a tattoo or pregnancy line in which a pigment is injected into this part The nature is also due to the nature of similar sites. Therefore, the epidermis pattern, which is the deep structure of the skin, is considered to be suitable for biometric authentication, but it may not be intuitively visible or may not leave traces even when touching an object. Although it has characteristics, it has not been considered as a personal authentication method.

  The present invention has been proposed in view of such a conventional situation, and an object of the present invention is to provide an authentication device capable of performing permanent biometric authentication without risk of “spoofing” due to forgery or the like.

The present invention is an authentication device, which is incident on a surface of the epidermis obliquely toward a vein region to be detected at a shallow angle, and irradiates light passing through the epidermal tissue and dermis tissue while being obliquely scattered. The vein pattern produced by the backscattered light absorbed by the veins in the vein area of the detection target, and the backscattered light generated by the light passing through the dermal tissue behind the vein area of the detection target And capture means for capturing the return light, and verification means for verifying the vein pattern of the return light captured by the capture means with the stored vein pattern.
The take-in means faces the epidermis surface part on the side where the vein area to be detected is located with respect to the direction in which the light emitted by the irradiation means obliquely passes through the epidermis and dermis tissues, and the vein area to be detected from the irradiation means Reflected light and scattered light generated until the light reaches the back of the light, and scattered light generated after the light passes through the vein region to be detected are mixed into the return light emitted from the surface of the epidermis. Includes shielding plate.

  As described above, according to the present invention, since a vein that hardly remains as a trace on other objects and is difficult to see is used, there is no risk of “spoofing” due to forgery or the like, and permanent biometric authentication is possible. Can be realized.

It is a schematic diagram of skin tissue. It is a schematic diagram which shows an example of the detection apparatus (authentication apparatus) which contrasts a dermis tissue using the depolarization by backscattered light. It is a schematic diagram which shows an example of the detection apparatus (authentication apparatus) which can image skin scattering at arbitrary depths. It is a schematic diagram explaining the principle of the birefringence measurement by an optical heterodyne interferometry. It is a schematic diagram which shows an example of the detection apparatus (authentication apparatus) which used the scattering characteristic pattern by skin light interference for epidermal tissue pattern detection. It is a schematic diagram which shows an example of the detection apparatus (authentication apparatus) which arranged multiple beat detection elements in the array form. It is a schematic diagram which shows an example of the detection apparatus (authentication apparatus) which used the movable mirror for the irradiation part to skin. It is a schematic diagram which shows an example of the detection apparatus (authentication apparatus) which specifies an authentication object area | region with a vein pattern. It is a characteristic view which shows the absorption spectrum of oxidation / reduction hemoglobin. It is a characteristic view which shows the difference of the permeability | transmittance of hemoglobin and water in a biological body. It is a schematic diagram which shows an example of the detection apparatus (authentication apparatus) which performs pattern detection by the differential interference of near infrared rays.

  Hereinafter, an authentication apparatus to which the present invention is applied will be described in detail with reference to the drawings.

  For example, in the case of biometric authentication using fingerprints, traces (fingerprints) are easily left on other objects, and since it is easy to see, the risk of being counterfeited by a third party cannot be denied. Requires a separate physiological affiliation identification to determine whether or not the finger is correct. This is because the biometric authentication by fingerprint directly captures the shape of the dead tissue by losing the nucleus such as skin stratum corneum.

  It can be said that the security strength of the above-mentioned fingerprint, iris, and other biometric authentication means depends not on detection accuracy but rather on this physiological bioaffiliation confirmation. For example, if biometric identification by fingerprint biometrics is broken, Therefore, it becomes possible to easily “spoof” by obtaining a biological tissue to be authenticated, and in this sense, the security strength of the system is equal to nothing. If the security of a general credit card, etc., breaks through it, economic loss alone will not cause any direct harm to the living body. However, “impersonation” due to the acquisition of the biological tissue described above is serious for the living body. The result is a new disaster. This is hereinafter referred to as a surgical hazard.

  In biometric authentication, in addition to the local security strength used in general authentication technology, the concept of security strength against surgical disasters is required as a new system, and security including user safety is also required. It is necessary to consider, but the point is not clarified in the prior art.

  In other words, security as biometric authentication is “biological tissue that matches the person's own thing and is not cut from the person's person” and “authentication” that identifies the normal living body to be authenticated. Although it depends on how reliable the two conditions of “affiliation identification” can be established, the conventional biometric authentication technology simply focuses on the accuracy and reliability of the former authentication. In this case, although it is referred to as biometric authentication, the target is actually authenticated without performing “biological affiliation identification”, and a contradiction arises that it is not actually “biometric” authentication. Therefore, when viewed as a security system including actual operation, it can be said that there is a possibility of inducing a secondary disaster called a surgical disaster from such a contradiction.

  The “spoofing method”, which is the simplest and does not require any technical knowledge or equipment, is a method in which a third party authenticates by cutting and extracting tissues such as fingers, arms, and eyes from a living body. Even if it is only possible to obtain an economic value that is equal to or less than a personal petty deposit, the introduction of such a biometric authentication method, on the other hand, causes serious damage that cannot be easily converted into money for the user's life and body. Result. For this reason, conventional biometric authentication methods such as fingerprints and eye irises are widely used as supplementary means for other authentication means, or are used in a vaguely limited form such as simple applications. It is difficult to spread.

  On the other hand, in the method that is relatively easy to counterfeit such as biometric authentication by fingerprint, for example, fingerprint authentication by capacitance is taken as an example, as a countermeasure against counterfeiting, the skin is exposed to humidity (moisture) containing salt such as sweat on the fingerprint surface. Attempts have been made to capture the fingerprint pattern by detecting the distance between the microelectrode and the skin surface by making the surface function as a conductor and measuring the capacitance and induction between the electrodes. This is an example of an attempt to identify bioaffiliation in a sense. This is because the above measurement is impossible unless there is electrolytic humidity containing salt such as sweat secreted from the living body.

  However, in this detection method, the presence of electrolytic humidity is necessary for the authentication target, but it is not necessarily derived from a living body, and other than this, for example, it is not cut out. Biological affiliation identification is not established. For this reason, it is difficult to eliminate imitations in which a fingerprint pattern is formed on a gel-like substance having water retention, or those obtained by spraying or immersing physiological saline on cut fingers.

  Also, with biometric authentication using DNA or the like, it is certainly difficult to “forge” DNA itself, but whether the DNA to be authenticated belongs to a living body, it is collected from a corpse or hair, PCR, etc. It is essentially impossible to determine whether a large number of copies have been made, and this is also a method in which biometric affiliation identification is not established. For this reason, in addition to the biometric authentication means, a measure such as adding a new sensor for identifying the living body by some method other than the biometric authentication itself, such as detection of blood flow of a finger by infrared rays, is required.

  Here, biometric authentication is separated into two types of “biometric / authentication”, and is different from biometric authentication. If authentication is a front door, authentication of the biometric affiliation identification of the authentication target is called authentication. Relying on another physical detection is a problem similar to making a back door. This contradiction is that if the backdoor's biometric affiliation identification means can be deceived, the security as the authentication system will break down at that time, and there is a risk of causing "spoofing" using objects or even a surgical disaster. Biological affiliation identification is to identify “living tissue” on the premise of biological organizations rich in diversity, but as it is clear even in Central Dogma, what life is, Due to the diversity, the frontage of identification becomes large, and as a result, there is an essential problem that deception is possible. In the conventional method that prepares the detection means used for biometric authentication and biometric affiliation identification separately, it can be said that the sensing method of biometric affiliation identification could be easily found and analyzed by a third party. Therefore, there is a need for a biometric authentication method in the true sense that authentication and biometric affiliation identification are integrated, and authentication = biological affiliation identification and there is no back door.

  Therefore, instead of using the epidermis pattern such as the above-described fingerprint, biometric authentication is performed by detecting an uneven protuberance distribution pattern of a deep skin tissue, for example, the dermis layer.

  FIG. 1 is a schematic diagram of a skin tissue, and the skin tissue is roughly composed of an epidermis 1 and a dermis 2. The epidermis 1 is a keratinized stratified squamous epithelial tissue, and is composed of a stratum corneum layer 11, a transparent layer 12, a granular layer 13, a spinous layer 14, a basal layer 15, and a basement membrane 16. Of these layers, the granule layer 13, the barbed layer 14, and the basal layer 15 are collectively referred to as a Malpiggy layer.

  The stratum corneum 11 has a lamellar liquid crystal form of a bilayer membrane of stratum corneum lipids, the transparent layer 12 has a cholesteric type liquid crystal form, and the granule layer 13 has optical properties such as beads called keratohyaline granules that reflect and scatter light. It contains a basic structure with specific properties in the cytoplasm. In addition, the base layer 15 has melanin granules, and optically has various scattering and absorption forms in each layer in order to protect the living body from external ultraviolet rays and the like. Especially for light in the ultraviolet band, the epidermis has certain dichroic properties due to the multilayer thin film structure having different refractive indexes. However, basically, the epidermis 1 is a translucent tissue having a relatively scattering property even in the visible light region except for coloring by melanin. However, the transparency is higher in a longer wavelength band than visible red or near infrared. For this reason, the blood flow in the capillary network of the dermis 2 under the epidermis 1 is scattered and can be observed from the outside as, for example, a face color or a blood color, and the skin color basically consists of the melanin pigment and the dermis 2. Determined by blood in capillaries. The epidermis 1 does not circulate electrolytes such as capillaries and lymph, and basically has a strong dielectric property as represented by the stratum corneum 11.

  On the other hand, the dermis 2 is completely different from the epidermis 1. Basically, the dermis 2 is composed of a dense connective tissue made of collagen or elastin and a capillary network, and is greatly different from the epidermis 1 which is a single cell aggregate and does not have capillaries.

  The dermis 2 is divided into a nipple layer and a mesh layer. The dermal papilla layer is a tissue in contact with the epidermal tissue through the basement membrane, which is the lowest layer of the epidermal tissue, and is composed of connective tissue and capillaries, and has sensory nerve endings. The network layer is composed of collagen having a certain arrangement structure, elastin connecting the collagen, and a matrix filling them. The dermis 2 is rich in capillaries and rich in electrolytes due to the circulation of lymph and the like. Therefore, the conductivity is remarkably higher than that of the epidermis 1.

  Further, collagen and elastic fibers forming the connective tissue of the dermis 2 have strong optical birefringence, but there is no birefringence in the epidermal tissue. Optically, the skin 1 also has a scattering property, and the polarization property causes depolarization with scattering. Basically, the horizontal / vertical polarization ratio depends on the size and shape of the scattering particles, and the wavelength of the electromagnetic waves exhibiting inherent scattering characteristics >> particle radius → Rayleigh scattered electromagnetic wave wavelength to particle radius → Mee scattering (cloud particle And cumulonimbus white clouds) Wavelength of electromagnetic wave <<< particle radius → geometrical electromagnetic wave progression (raindrop) (rainbow, diamond dust)

  The dermis 1 is like a milk agar, and looks white only after a certain thickness. In addition, the dermis 1 has a property that light having a longer wavelength is more easily transmitted and light that is shorter is easily scattered. If the light-absorbing dye is present in a negligible amount in the dermis 1, short-wavelength light scattered at a shallow depth of the dermis 1 has a high rate of returning to the eyes of the observer, but long-wavelength light is transmitted and absorbed by the dye. And the rate of return will be lower. For this reason, capillaries in the shallow part of the skin look bright red, but veins and hemangiomas in slightly deeper parts appear bluish. Melanocyte-related nevus (bruise) appears to be brown in the border nevus where nevus cells are present at the dermis / epidermal boundary, but the blue nevus in the dermis appears to be blue as its name suggests, and dermal melanocytes Ota's nevus and Mongolia are also clinically bluish.

  By utilizing the difference between these optical characteristics and electrical characteristics, an uneven ridge distribution pattern or the like of deep skin tissue (for example, dermal tissue) is detected and used for biometric authentication. For example, by filtering focusing on the wavelength component of reflected light with respect to white light and scattering / polarization characteristics, the dermis layer characterized by deeper connective tissue and collagen fibers can be distinguished from the epidermal tissue. It is possible to clarify dermal tissue that is shielded by the epidermis and difficult to see, especially in the whole body skin and subcutaneous tissue other than special places where the dermis layer pattern and the epidermis layer pattern match, such as fingerprints Individual authentication can be performed by detecting the pattern.

  FIG. 2 shows an example of the configuration of a detection device that optically captures the dermis of the epidermis having such a wide variety of scattering forms. By suppressing light reflection and transmitting light due to scattering and birefringence, it is possible to image an uneven ridge distribution pattern under the epidermis.

  Specifically, first, as an irradiation optical system, a light source 21, an optical lens 22, and an irradiation unit polarizing plate 23 are provided. An arbitrary light source such as an LED can be used as the light source 21. However, as the light source 21, it is preferable to use a light source that emits long-wavelength light such as near infrared rays that is transmitted through the epidermis and scattered by the dermis, and thereby optical characteristics such as scattering and birefringence in the epidermis. It becomes possible to obtain the pattern of the organization using.

  Further, the imaging optical system includes an imaging element (for example, a solid-state imaging element: CCD) 24 that is a light receiving element, an imaging lens group 25, and a light receiving unit polarizing plate 26. Further, a half mirror 27 is disposed in the optical path between the irradiation optical system and the imaging optical system, and the irradiation optical system and the imaging optical system are arranged orthogonal to each other.

  In the above-described detection device, the irradiation light from the light source 21 is irradiated to the skin with the vibration direction limited to one direction by the irradiation unit polarizing plate 23. In addition, a light receiving part polarizing plate 26 is disposed in the imaging optical system, and this is configured such that the vibration direction is orthogonal to the projection part polarizing plate 23. Therefore, the simple reflected light from the skin tissue has a vibration direction orthogonal to the light receiving part polarizing plate 26 and is shielded by the light receiving part polarizing plate 26.

  Irradiation light irradiated to the skin from the irradiation optical system reaches deep skin tissue (for example, dermal tissue), and scattering and birefringence are caused by various tissues, thereby depolarizing the polarized light. These are transmitted as a backscattered light through the half mirror 27 and guided to the imaging optical system. However, as described above, since the polarization is eliminated, the light passes through the light-receiving unit polarizing plate 26 and reaches the image sensor 24. .

  Light reflected or scattered via tissue that has optically birefringent properties, such as connective tissue and collagen that are not present in the epidermal tissue and that are inherent in the dermal tissue, etc., shifts in phase from the incident light due to birefringence. become. This makes it possible to distinguish between reflected / scattered light from the epidermal tissue and light having different phases via the birefringent tissue (dermis tissue).

  In this configuration, a band filter such as a dichroic filter selectively transmits only the wavelength component of the phase shift due to birefringence in the dermal tissue, and by detecting this, the birefringent tissue is selectively detected to detect the dermal tissue. A method for noninvasive detection from outside the body is also conceivable.

  As a skin measurement using polarized light, a method of using polarized light for observing the skin by paying attention to the optical characteristics of a polarizing filter in the visible light band is known in the field of the beauty industry. For example, a method for evaluating the skin surface is known as a method for measuring cosmetic elements such as skin gloss and brightness (see Japanese Patent No. 3194152 and Japanese Utility Model Publication No. 7-22655).

  However, these are not intended for observing subepidermal tissues such as dermis tissues, but for the purpose of evaluating the skin surface with a cosmetic appearance using visible light. Therefore, by utilizing the well-known property that polarized light is eliminated by scattering, image quality deterioration due to glare of direct reflection such as epidermal keratin is prevented, and a stable epidermal image is obtained by obtaining an image due to visible light scattering of the epidermis. It is only disclosed to obtain.

  Since these conventional methods use visible light, the dermis layer state is accurately detected because visible light is absorbed and shielded by the melanin pigments of spinous cells and basal cells, even though scattering of the epidermis can be captured. It is difficult. For this reason, it is also difficult to classify an image due to birefringence of the dermal tissue. Focusing on the optical properties that have strong anisotropy compared to the epidermis, such as connective tissue and collagen tissue of the dermis layer, and birefringence occurs, and the epidermal tissue is visible light for near infrared light Unlikely, there is no knowledge of capturing the dermis layer structure by using the scattering property and birefringence of dense connective tissue that constitutes the dermis layer, and it was proposed for the first time by this application. Is.

  As described above, by using the detection device, it is possible to capture a dermis layer structure (for example, an uneven ridge distribution pattern) using the scattering characteristics and birefringence of dense connective tissue constituting the dermis layer. However, when the detection apparatus is configured as shown in FIG. 2, scattering due to the epidermis layer, scattering due to dermis tissue or subcutaneous tissue below the surface of the dermis layer to be detected is mixed as noise, and the SN ratio is increased. There is concern about the decline. Therefore, as a method for dealing with this, it is effective to reduce the incident angle of the irradiated light to the skin and limit the aperture of the imaging optical system, for example, as shown in FIG.

  In the detection apparatus shown in FIG. 3, a movable reflecting mirror 28 is added to the irradiation optical system, the irradiation light from the irradiation optical system is irradiated obliquely to the skin, and the imaging optical system is disposed directly above the target region. The back scattered light and the side scattered light are directly detected without passing through the half mirror 27. Further, the imaging optical system is provided with a light shielding plate 29 for limiting the opening thereof, and is configured so that only return light from directly below reaches the image sensor 24.

  In such a detection apparatus, the irradiation light from the irradiation optical system enters obliquely from the epidermis layer to the deep skin tissue (dermis layer). At this time, in the shallow portion, that is, the epidermis tissue, the incident light is scattered in the right region in the drawing and does not reach the imaging optical system whose opening is limited by the light shielding plate 29. Similarly, in a deeper portion, incident light is scattered in the left region in the figure, and the scattered light does not reach the imaging optical system. On the other hand, if the angle of the movable reflecting mirror 28 is adjusted so that the irradiation position on the dermis tissue is directly below the imaging optical system, only the scattered light in this region (dermis tissue) is obtained. Reaches the imaging optical system.

  Next, a detection method using the birefringence of the dermal tissue will be described. First, as a general birefringence measurement method, not the bandpass filter as described above but the fact that the phase difference between the two lights of the irradiation light and the reflected light or transmitted light is converted into the phase difference of the beat signal is used. It is conceivable to use optical heterodyne interferometry.

  FIG. 4 is a principle diagram in that case. The sample 33 is irradiated with oscillation light from a light source, for example, a stabilized transverse Zeeman laser (STZL) 31 through a half mirror 32, and transmitted light (signal) transmitted through the polarizing plate 34. Light) is detected by the photodetector 35. At the same time, of the oscillation light from the stabilized lateral Zeeman laser 31, the light reflected by the half mirror 32 and the transmitted light (reference light) transmitted through the polarizing plate 36 are detected by the photodetector 37. Then, the phase difference of the detection light detected by each of the photodetectors 35 and 37 is measured by the electric phase meter 38.

  Here, the linear polarizer (polarizing plates 34 and 36) is used to cause the two lights to interfere with each other, and birefringence measurement can be performed with the measurement accuracy of the electric phase meter 38. In general, the measurement accuracy of the electric phase meter 38 is 0.1 degree (or higher), so that it is possible to measure the birefringence with a high accuracy of about 1/4000 of the wavelength of light.

  The principle of the optical heterodyne interferometry is as follows. First, assuming that the electric field components of the reference light and the signal light are Er and Es, they can be expressed as follows.

  Here, ar and as represent the amplitudes of the reference light and the signal light, respectively. Similarly, fr, fs, φr, and φs represent the respective frequencies and phases. When these two lights are superposed, the detected light intensity I becomes equal to the square of the electric field component, so that the following is obtained.

  In the formula, <> represents a time average. Also, fb (= fs-fr) represents the optical beat frequency, and Δ (= φs−φr) represents the phase difference between the two optical components.

  In the photocurrent component detected by the photodetector, the first and second terms of the equation (3) are DC components, and the third term is an AC component that changes in a sine wave shape at the frequency fb. This AC signal is referred to as an optical beat signal. In optical heterodyne interferometry, the amplitude (2as · ar), frequency (fb), or phase difference (Δ) of an optical beat signal is electrically measured, and the amplitude (as), frequency (fs), phase ( The information included in φs) is extracted.

  In the measurement of the dermal tissue, specifically, when the refractive index of birefringent skin tissue is nx, ny, and the thickness through which light is transmitted is d, the phase delays φx, φy generated after transmission are as follows: It can be expressed as equations (4) and (5).

  When STZL (stabilized transverse Zeeman laser) oscillation light or the like is transmitted through the sample as two lights having slightly different frequencies, the light intensity signal I obtained by the photodetector is expressed as follows.

  Here, Δ represents the phase difference of the two-component light, and δn represents the refractive index difference (= birefringence amount). From the equation (6), it can be seen that the phase difference between the two lights is converted into the phase difference between the beat signals. By this, the birefringence is obtained by measuring the phase of the optical beat signal with the electric phase meter 38 or the like. The amount can be measured.

  At this time, the problem is that the orientation of the birefringent principal axis of the skin tissue needs to be obtained in advance and the orientation of the principal axis needs to be exactly matched to the oscillation polarization plane of the STZL. For this reason, the polarization plane of the STZL oscillation light It is necessary to detect the phase difference while rotating the lens around the optical axis and simultaneously obtain the amount of birefringence and its principal axis direction. Therefore, in such a method, an apparatus used for authentication is extremely complicated and complicated to operate, and it takes a long time to detect. In addition, when a wrist-worn or other human body-mounted authentication apparatus is used, it is necessary to strictly determine the mounting position and direction at the time of wearing. In addition, it is necessary to take measures such as bringing the body into close contact with the living body so that it does not move even if the living body is active.

  Therefore, in the above case, the skin surface to be detected is set as a branch portion of the subcutaneous blood vessel. By using the shape of the branch, the main axis direction can be easily determined. For example, if the positional relationship between the main axis direction and the branching part is determined and recorded in advance at the time of registration, the main axis can be easily matched from the position and direction of the blood vessel branching part at the time of authentication.

  Alternatively, this can be addressed, for example, by detecting deep skin structures by interference. Thus, it is not to measure the birefringence itself, but to capture the characteristic of the living body inside the skin through birefringence and scattering. Therefore, paying attention to the frequency change that occurs when the light projected on the skin is backscattered or birefringent in the internal tissue of the skin such as the dermis layer, directly interferes with the scattered light from the skin and the projected light without using a polarizer. By detecting this, the frequency change is detected as a beat.

  FIG. 5 shows a configuration example of such a detection apparatus. In this detection apparatus, as in the detection apparatus shown in FIG. 2, an irradiation optical system including an irradiation light source 41 and an optical lens 42, and an imaging optical system including an imaging element 43 such as a CCD and an optical lens 44 are half mirrors 45. It is arranged orthogonally via. However, unlike the detection apparatus shown in FIG. 2, the irradiation optical system and the imaging optical system are not provided with a polarizing plate. Instead, a reference mirror 46 that guides a part of the irradiation light from the light source 41 of the irradiation optical system to the imaging element 43 of the imaging optical system is provided.

  A part of the light emitted from the light source 41 such as a white LED is irradiated to the skin surface via the half mirror 45. A part of this irradiated light returns to the half mirror 45 again after undergoing various reflections, scattering, birefringence and the like inside the skin. This light and the light reflected from the half mirror 45 to the reference mirror 46 during irradiation cause a beat (interference), and the interference pattern is imaged on the image sensor 43.

  At this time, by generating the beat for each point in the detection area of the skin, a continuous epidermal pattern can be obtained from the beat pattern. In order to select such a continuous pattern, specifically, a method of arranging a plurality of the beat detection elements in an array form as shown in FIG. 6 or a movable mirror on the light irradiation part to the skin as shown in FIG. And the like. In the former case, an irradiation optical system including the irradiation light source 41 and the optical lens 42 and an imaging optical system including an imaging element 43 such as a CCD and an optical lens 44 are arranged orthogonally via a half mirror 45. A plurality of beat detection elements 50 are arranged in a so-called array, and a subepidermal continuous pattern is obtained based on a detection signal from each beat detection element 50.

  On the other hand, in the latter case, irradiation of irradiation light from the beat detection element 50 and detection of return light are performed by the movable mirror 51. The angle of the movable mirror 51 is controlled by the mirror control unit 52, and the mirror control unit 52 controls the angle of the possible mirror 51 based on the control information from the angle-interference pattern matching unit 53. Interference pattern information is sent from the beat detection element 50 to the angle-interference pattern matching unit 53. The interference pattern sent to the angle-interference pattern matching unit 53 includes the interference pattern stored in the skin interference pattern storage unit 54 and the skin registered in advance. The interference pattern storage / collation unit 55 collates and performs biometric authentication.

  Since these methods do not use a polarizer that was necessary for detecting a phase difference or the like, it is not necessary to precisely align the optical axis. Even if the direction changes due to loose attachment to the human body, there is an effect that it is hardly affected.

  However, when there is actually a looseness of wearing, it is necessary to specify specifically which side of the skin is subject to authentication. Although a method of previously registering an interference pattern of a wide skin region including the target region is conceivable, it is necessary to collate a specific pattern from a pattern of a wide region, which causes a large processing load. In the case of a portable device, such a large load is not preferable in terms of power consumption.

  For example, in biometric authentication using skin pattern, the center of vortex, horseshoe, etc. is easily captured in special cases such as fingerprints, and the position of the authentication target is determined because the finger surface shape is limited and narrow. It is easy to identify. However, in general skin excluding such limited and unique parts, the area is also wider than the fingertips, and a fine skin pattern that does not have a geometrical shape that is easy to locate, such as a vortex, like a fingerprint It is extremely difficult to specify an authentication target area from among the above.

  For this reason, as described above, it is possible to register a skin pattern in a wide area in advance and search for whether the pattern detected at the time of authentication is included in the registration pattern. In addition, it takes a processing load and time for the apparatus for verification at the time of authentication. In addition, registration of the whole body skin pattern is ideal, but it is not practical for the above reasons, and in that case, the definition of “wide area” is ambiguous. Due to the difference in the contacts to be authenticated to the authentication device, there is a possibility that the authentication device may fall out of the area at the time of individual authentication.

  Therefore, the following method is effective as a method for specifying the authentication target area of the skin. That is, the backscattered light from the subcutaneous tissue of the living body is used as the projection light, using near infrared light having a wavelength that is exceptionally absorbed by reduced hemoglobin such as venous blood instead of white light. The vein pattern is detected, and the authentication target area is specified using the vein pattern. By setting the authentication target area on a specific vein or skin surface such as a vein bifurcation, even if the skin contact surface of a personal authentication device such as a wristwatch is misaligned or loosened on the living body of the device The same skin area that is always subject to authentication can be reliably identified.

  FIG. 8 shows an example of a detection device that identifies an authentication target area using a vein pattern. The detection apparatus shown in FIG. 8 has the same apparatus configuration as that of FIG. 7, but uses a near-infrared light source as the light source 41 of the beat detection element 50, and uses a skin vein position detection unit 61 and a skin vein position collation unit 62. In addition, a vein data storage unit 63 for storing vein data is added. By adopting such a configuration, it is possible to obtain a capillary blood vessel image of the dermal skin vein 60 existing in the shallowest part of the skin.

  The near-infrared band having a wavelength of 700 to 1200 nm has a specific low absorbance in a living body and is called a “spectral region window”, and penetrates living tissue well. What is important here is that the epidermis tissue reflects and scatters visible light and ultraviolet light, but nearly 80% of light in this band is transmitted. On the other hand, in the near-infrared band having such characteristics, there is a wavelength that is easily absorbed by hemoglobin in blood. As shown in FIG. 9, at a wavelength of 805 nm, oxygenated hemoglobin (HbO 2) and reduced form are present. The absorbances of hemoglobin (Hb) coincide with each other, but reduced hemoglobin (Hb) has a higher absorbance at a wavelength of 660 nm, and oxygenated hemoglobin (HbO2) has a higher absorbance at a wavelength of 940 nm. Furthermore, as shown in FIG. 10, the spectral characteristics of hemoglobin and water in the living body are also greatly different.

  By utilizing this characteristic, a blood vessel image can be obtained by distinguishing it from water in the living body, and arteries and veins can be identified from the absorbance by wavelength. In order to obtain a vein pattern, for example, a near-infrared irradiation means of 805 nm is provided in the light source, and this is irradiated to the skin through a polarizing plate. Irradiated light is detected as a return light that is a combination of light reflected, scattered, and birefringent from the skin, but the reflection on the skin surface hinders the acquisition of images below it. Then, the image is taken with a CCD camera or the like through a polarizing plate disposed at an angle at which the vibration direction is orthogonal to the polarizing plate. As a result, the reflected light having the same vibration direction by the tissue such as the epidermis, transparent layer, granule layer and the like is filtered, and only the scattered light and the birefringent wave whose polarization has been eliminated are photographed.

  In the detection apparatus shown in FIG. 2 and FIG. 3, scattering due to scattering other than the detection target tissue should be excluded when capturing the dermis layer, but here the irradiation wavelength is selectively absorbed by the capillary of the dermis layer. Unlike the case of using a white light source, the capillary pattern of the dermis layer is clear against the backscattering in the deeper part because the absorbance of the skin tissue other than hemoglobin other than hemoglobin is low and the permeability is high. Can get to.

  The pattern formed by the blood flow of the capillaries is unique to the living body. When the tissue is cut from the living body, it immediately disappears due to vascular atrophy, blood flow cessation, blood loss, or the like. Further, by using the absorption band of oxygenated hemoglobin of 940 nm, it is possible to detect that the absorbance changes according to the pulsation of the pulse and to recognize the affiliation of the living body together with the pattern by the subcutaneous capillary. Furthermore, by utilizing the fact that there is a difference in absorption characteristics such as deoxygenated hemoglobin having a high absorbance at a wavelength of 660 nm, and oxygenated hemoglobin having a high absorbance at a wavelength of 940 nm, for example, in a cut tissue, the tissue is caused by cessation of pulmonary circulation. It is also easy to add a method to distinguish between normal biological tissue and severed tissue by detecting that the oxygen saturation of the selenium significantly decreases, and as a result, the absorbance of 940 nm oxygenated hemoglobin decreases and disappears. is there.

  As a result, the biometric authentication and the biometric affiliation recognition coincide with each other, so even if the cut tissue is immersed in physiological saline or the like and the cells are kept alive, the blood flow does not exist so that the authentication can be excluded. Is. The tissue to be certified must have the pulmonary circulation and pulsation and the correct blood flow and blood hemoglobin ratio. Even if the arm is surgically cut and used, the blood vessels of the arm are surgically removed. It is necessary to connect to a heart-lung machine and accurately reproduce the pulsation waveform. For example, it is difficult to realize in a present situation where a portable heart-lung machine has not been put into practical use. Even if it is put to practical use in the future, it begins with the cutting of the arm, connection to each blood vessel and device, treatment for the cut microvessels and nerves, elimination of tissue changes due to living reactions to cutting, and resumption of blood flow It requires advanced surgical techniques and medical equipment, such as stabilization of later tissues, and is not a realistic task. On the other hand, it is more difficult to accurately construct the same thing artificially, such as a three-dimensional structure or scattering of fine capillaries, without using a living body.

  Next, epidermal pattern detection by differential interference will be described. The differential interference method is one of the observation methods using a microscope, and is a method of stereoscopically observing a phase difference of illumination light caused by a difference in thickness and refractive index of a sample with light and dark or color contrast. The dermis layer is difficult to detect by a normal bright-field optical system or a visual method. Therefore, we focused on the fact that cell nuclei and the like that are difficult to see without staining with a normal microscope can be observed with a differential interference optical system. However, even if this is possible when the dermis layer is exposed, it is difficult to apply it to the dermis layer as it is. When the skin layer is covered, it is difficult to detect the dermis layer as it is because of the reflection, scattering and shielding by the skin layer even though the surface of the skin layer can be observed.

  Therefore, paying attention to the fact that the skin layer is highly transparent in the red-near infrared light band, white light is used as a light source in a normal differential interference mirror, whereas a near infrared light source and a near infrared CCD are used. We will use it. Thereby, it becomes possible to detect the uneven | corrugated pattern of an epidermal dermis layer noninvasively.

  A specific example is shown in FIG. This detection apparatus includes an irradiation optical system having a near-infrared light source 71 and a polarizing prism 72, and an imaging optical system having an imaging element 73 such as a CCD and a polarizing prism 74, which sandwich a half mirror 75. They are arranged orthogonally. Irradiation light from the irradiation optical system is reflected by the half mirror 75 and applied to the skin, and return light (reflected light) passes through the half mirror 75 and reaches the imaging optical system. A Wollaston prism 76 and an objective lens 77 are arranged in the optical path between them.

  Irradiation light emitted from the near-infrared light source 71 is converted into light having a uniform polarization direction by the polarizing prism 72 and reflected by the half mirror 75 in the direction of the Wollaston prism 76. The irradiation light incident on the Wollaston prism 76 is separated into two light beams (light beams A and B) whose polarization directions are orthogonal to each other, and is irradiated onto the object (skin). At this time, the distance between the light beam A and the light beam B is less than the resolution of the objective lens. Further, the two light beams reflected by the object are again combined into one light by the Wollaston prism 76, and after passing through the half mirror 75, the polarization direction is aligned by the polarizing prism 74. When the two light beams A and B are reflected by the stepped portion, an optical path difference is generated between them and interferes when passing through the polarizing prism 74. When the optical path difference is ½ of the wavelength of the light rays A and B, the light beams interfere and become the strongest. This interference pattern can be viewed with a differential interference mirror using a normal white light source, and a transparent object can be observed three-dimensionally, but since it is difficult to see in the near infrared band, a CCD capable of imaging the near infrared band. Visualization is performed using an imaging element 73 such as.

  The present invention can be used in the authentication field using information unique to a living body.

  DESCRIPTION OF SYMBOLS 1 ... Epidermis, 2 ... Dermis, 21, 41 ... Light source, 23, 26 ... Polarizing plate, 24, 43 ... Imaging element, 27, 45 ... Half mirror, 46 ... Reference mirror.

Claims (4)

Incident means for irradiating light that passes through the epidermis and dermis tissues obliquely with respect to the surface of the epidermis, incident at a shallow angle toward the vein region to be detected, and
With the backscattered light generated by the light passing through the dermal tissue behind the vein area of the detection target as a background, the vein pattern generated by the vein of the vein area of the detection target absorbing the backscattered light Capturing means for capturing return light including:
Collating means for collating the vein pattern of the return light captured by the capturing means with the stored vein pattern;
The capturing means is
The light irradiated by the irradiation means is opposed to the surface area of the skin on the side where the vein area of the detection target is present with respect to the direction in which the light passing through the epidermis and dermis tissues obliquely, and from the irradiation means of the vein area of the detection target Reflected light and scattered light generated until the light reaches the back and scattered light generated after the light passes behind the vein region to be detected are mixed in the return light emitted from the surface portion of the epidermis. An authentication apparatus comprising a shielding plate for blocking the situation. The shielding plate is
The authentication apparatus according to claim 1, wherein return light emitted from the surface portion of the skin is guided to an objective lens provided in the shielding space. The capturing means is
The authentication device according to claim 2, wherein the return light is captured in a direction orthogonal to the interface between the epidermal tissue and the dermis tissue or in the direction opposite to the irradiation side. The irradiation means is
In order to suppress a decrease in the S / N ratio due to emission of scattered light generated in the shallow part of the epidermis from the epidermis surface part where the return light should be taken in, it is incident at a shallow angle on the epidermis surface away from the epidermis surface part. The authentication device according to claim 1.

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