KR100852828B1 - Vein authentication device - Google Patents

Abstract

The present invention processes an interface on which a living body to be imaged is placed, a light source that emits infrared light, an imaging unit which picks up a blood vessel image of the living body by light from the light source, and a blood vessel image picked up by the imaging unit. A vein authentication device comprising an image calculating unit, wherein the interface forms an opening opening in the imaging direction of the imaging unit, and the light source irradiates the living body with infrared light from the imaging side of the living body, and radiates from the light source. It characterized by including a light shielding portion that shields infrared light so that infrared light does not face the imaging direction.

Infrared light, light source, blood vessel image, imaging unit, vein authentication device, light shielding unit, image calculating unit, light amount adjusting unit

Description

Vein authentication device {VEIN AUTHENTICATION DEVICE}

The present invention relates to an authentication apparatus for authenticating an individual, and more particularly, to a technique for authenticating using vein information of a living body.

Recently, security of personal information is becoming important. Biomatrix authentication is attracting attention as a security personal authentication technology. Biomatrix authentication is a technology that authenticates using human biometric information, and is excellent in convenience and confidentiality.

As a conventional biomatrix authentication technique, authentication using veins of finger, iris, voice, face, hand, or finger vein is known. In particular, in the biomatrix authentication using veins, the user can authenticate by simply presenting a part of a living body such as a hand or a finger to the authentication device. Therefore, biomatrix authentication (vein authentication device) using veins has low psychological resistance of the user. In addition, since the vein authentication device uses the internal information of the living body, the forgery resistance is excellent.

Hereinafter, the finger vein authentication apparatus is described in particular.

First, the finger vein authentication device irradiates infrared light on a finger. Then, the infrared light is scattered inside the finger and then transmitted to the outside. The finger vein authentication device captures the infrared light transmitted from the palm side of the finger.

At this time, hemoglobin in the blood also absorbs infrared light from surrounding tissues. Therefore, the image picked up by the finger vein authentication apparatus visualizes the blood vessel (finger vein) distributed subcutaneously on the palm side of the finger as a dark shadow pattern (finger vein pattern).

The finger vein authentication device registers the characteristics of this finger vein pattern in advance.

The finger vein authentication apparatus captures an image of a finger presented by the user during authentication. Then, the finger vein authentication device performs personal authentication by obtaining a correlation between the finger vein pattern of the captured image and the pre-registered feature.

However, the conventional finger vein authentication apparatus images a finger inserted inside the apparatus. Therefore, the user feels resistance because he has to insert a finger into the occluded interior space of the finger vein authentication device.

Therefore, a finger vein authentication device that solves this problem is described in Japanese Patent Laid-Open No. 2004-265269. This finger vein authentication device installs light sources of infrared light irradiated to the fingers on both sides of the finger. This allows the user to authenticate by simply placing his or her finger on the device.

However, this finger vein authentication device has a problem that it cannot be miniaturized because a space for installing a light source is required on the side of the finger.

On the other hand, a vein authentication device having a flat structure is described in International Publication No. 2002/099393 pamphlet.

This vein authentication apparatus installs a light source on the same plane as the image pickup device for the vein to be photographed.

<Start of invention>

However, the vein authentication device which installs a light source on the same surface as the imaging element also picks up the light reflected from the skin surface of the finger. For this reason, there has been a problem that the vein authentication device cannot image vein patterns clearly.

Accordingly, the present invention has been made in view of the above-described problems, and an object thereof is to provide a vein authentication apparatus capable of capturing a clear vein pattern and miniaturizing it.

The present invention processes an interface on which a living body to be imaged is placed, a light source that emits infrared light, an imaging unit which picks up a blood vessel image of the living body by light from the light source, and a blood vessel image picked up by the imaging unit. A vein authentication device comprising an image calculating unit, wherein the interface forms an opening opening in the imaging direction of the imaging unit, and the light source irradiates the living body with infrared light from the imaging side of the living body, and radiates from the light source. And a light shielding portion that shields infrared light so that infrared light does not face the imaging direction.

The vein authentication apparatus of the present invention can image a vein pattern clearly. It can also be miniaturized.

1 is a configuration diagram of an authentication system according to a first embodiment of the present invention.

Fig. 2 is a block diagram of a memory of the authentication processing unit in the first embodiment of the present invention.

Fig. 3A is a side view of the input device of the first embodiment of the present invention.

3B is a front view of the input device according to the first embodiment of the present invention.

3C is a plan view of the input device according to the first embodiment of the present invention.

4A is an explanatory diagram of the effect according to the shape of the finger rest of the first embodiment of the present invention.

4B is an explanatory view of the effect according to the shape of the finger rest of the first embodiment of the present invention.

5A is an explanatory diagram of the effect according to the shape of the finger rest of the first embodiment of the present invention.

5B is an explanatory view of the effect according to the shape of the finger rest of the first embodiment of the present invention.

6 is an explanatory diagram of a relationship between a distance from a light source and a luminance value of a finger vein pattern image according to the first embodiment of the present invention;

7 is a flowchart of the authentication processing of the authentication processing unit according to the first embodiment of the present invention.

8A is an explanatory diagram of a finger vein captured by an imaging device of a first embodiment of the present invention;

8B is an explanatory diagram of an image picked up by the imaging device of the first embodiment of the present invention;

8C is an explanatory diagram of characteristic data converted by the authentication processing unit according to the first embodiment of the present invention.

9 is an explanatory diagram of characteristic data joining processing of an authentication processing unit according to the first embodiment of the present invention;

10 is a side view of an input device according to a second embodiment of the present invention.

11A is a plan view of an input device according to a third embodiment of the present invention.

11B is an explanatory diagram of a light source of an input device according to a third embodiment of the present invention.

11C is a front view of the input device according to the third embodiment of the present invention.

12 is a front view of an input device according to a fourth embodiment of the present invention.

It is a side view of the input device of 5th Embodiment of this invention.

14 is a side view of an input device according to a sixth embodiment of the present invention.

Fig. 15 is an explanatory diagram of a relationship between a distance from a light source and a luminance value of a finger vein pattern image according to the sixth embodiment of the present invention.

Fig. 16A is an explanatory diagram of an image picked up when the light source at the source side of the finger of the sixth embodiment of the present invention is strong.

Fig. 16B is an explanatory diagram of an image picked up when the light source at the fingertip side of the sixth embodiment of the present invention is strong;

Fig. 16C is an explanatory diagram of an image synthesized by the authentication processing unit in the sixth embodiment of the present invention.

17A is an explanatory diagram of an information portable terminal according to a seventh embodiment of the present invention.

Fig. 17B is a side view of an input device mounted on the information portable terminal according to the seventh embodiment of the present invention.

18A is an explanatory diagram of an information portable terminal according to an eighth embodiment of the present invention.

Fig. 18B is a front view of the input device mounted on the information portable terminal of the eighth embodiment of the present invention.

Fig. 19A is an explanatory diagram of a door knob of a ninth embodiment of the present invention.

Fig. 19B is a side view of an input device mounted on a door knob of the ninth embodiment of the present invention.

20A is a probe type authentication device of a tenth embodiment of the present invention.

20B is a side view of an input device applied to a probe type authentication device of a tenth embodiment of the present invention.

<Best Mode for Carrying Out the Invention>

EMBODIMENT OF THE INVENTION Hereinafter, embodiment of this invention is described with reference to drawings. In addition, although the vein authentication apparatus of a finger is demonstrated especially in this embodiment, other living bodies, such as a palm, are adaptable.

(1st embodiment)

1 is a configuration diagram of an authentication system according to a first embodiment of the present invention.

The authentication system includes an input device 2, an authentication processing unit 10, a storage device 14, a display unit 15, an input unit 16, a speaker 17, and an image input unit 18.

The input device 2 will be described later in FIGS. 3A, 3B and 3C. The input device 2 also includes a light source 23 and an imaging device 29.

The light source 23 is an infrared LED, for example, and irradiates infrared light to the finger 1 presented on the input device 2. The imaging device 29 picks up the finger 1 presented to the input device 2.

The image input unit 18 inputs the image captured by the imaging device 29 of the input device 2 to the authentication processing unit 10.

The authentication processing unit 10 includes a CPU 11, a memory 12, and an interface (IF) 13.

The CPU 11 executes various processes by executing a program stored in the memory 12. The memory 12 stores a program executed by the CPU, as will be described later with reference to FIG. 2. The memory 12 also temporarily stores an image input from the image input unit 18.

The interface 13 connects with a device external to the authentication processing unit 10. Specifically, the interface 13 is connected to the input device 2, the storage device 14, the display unit 15, the input unit 16, the speaker 17, the image input unit 18, or the like.

The storage device 14 previously stores the verification data of the user. The collation data is information for collating the user, for example, an image of a finger vein pattern. The image of the finger vein pattern is an image captured as a dark shadow pattern of blood vessels (finger veins) distributed under the palm of the finger.

The display unit 15 is, for example, a liquid crystal display and displays information received from the authentication processing unit 10.

The input unit 16 is, for example, a keyboard and transmits information input from the user to the authentication processing unit 10. The speaker 17 transmits the information received from the authentication processing unit 10 by voice.

Hereinafter, the authentication process of the authentication system of this embodiment is demonstrated.

First, a user who requests authentication presents a finger 1 to the input device 2. Then, the light source 23 provided in the input device 2 irradiates infrared light to the finger 1. This infrared light scatters in all directions inside the finger 1.

The imaging device 29 provided in the input device 2 captures the infrared light emitted from the palm side of the finger. The imaging device 29 inputs the captured image to the authentication processing unit 10 through the image input unit 18.

Then, the authentication processing unit 10 stores the input image in the memory 12. Then, the feature data is extracted from the image stored in the memory 12.

Next, the authentication processing unit 10 acquires authentication data stored in advance in the storage device 14 from the storage device 14. In addition, the authentication processing unit 10 may acquire only authentication data corresponding to the information (for example, user ID, etc.) input from the input unit 16 from the storage device 14. Next, the acquired authentication information is stored in the memory 12.

Next, the authentication processing unit 10 checks the extracted feature data with the authentication data acquired from the storage device 14. Specifically, the person who presented the finger 1 to the input device 2 is identified by calculating the upper threshold value of the feature data and the authentication data.

And the authentication processing part 10 performs the process corresponding to a specific person.

As described above, the authentication system of the present embodiment authenticates the user.

2 is a block diagram of the memory 12 of the authentication processing unit 10 of the first embodiment of the present invention.

The memory 12 stores a finger detection program 121, a light amount control program 122, a feature extraction program 123, a feature data bonding program 124, a feature matching program 125, and the like.

The finger detection program 121 determines whether or not the finger 1 is placed on the input device 2.

The light amount control program 122 controls the light amount of the light source 23.

The feature extraction program 123 extracts feature data from an image picked up by the imaging device 29.

The feature data joining program 124 joins the feature data extracted by the feature extraction program 123 with the feature data extracted in the past.

The feature collation program 125 collates the feature data bonded by the feature data joining program 124 with the authentication data stored in the storage device 14.

3A is a side view of the input device 2 according to the first embodiment of the present invention. 3B is a front view of the input device 2 according to the first embodiment of the present invention. 3C is a plan view of the input device 2 according to the first embodiment of the present invention.

The input device 2 of this embodiment demonstrates a swept-type finger vein authentication device as an example. In the swept finger vein authentication device, the user photographs the entire finger 1 by moving the finger 1.

Two finger holders 25 are provided on the upper portion of the input device 2 as an interface for installing a living body as an imaging target. In addition, two finger rests 25 are provided to form an opening 30.

The opening 30 may be transparent to infrared light, may be a simple space, or may be a transparent member to infrared light. In addition, the opening 30 makes the width in the longitudinal direction of the finger 1 narrower than the length of the finger 1. Thereby, the input device 2 can be miniaturized.

The finger holder 25 may be integrated with the input device 2 or may be configured separately from the input device 2. In addition, the finger holder 25 is made of an opaque material against infrared light.

In addition, the finger rest 25 is curved shape according to the shape of the finger 1 (refer FIG. 3B). The finger holder 25 is concave in the center.

This allows the user to place a finger at a predetermined position. In addition, the user can stably move the finger 1. As a result, the authentication precision of the authentication system of this embodiment can be improved.

In addition, the finger rest 25 may be a planar shape instead of the shape which has a curved recessed part. In this case, the finger holder 25 has no irregularities. Thereby, the upper part of the input device 2 can be made into a planar structure. In addition, the finger holder 25 is an example of an interface in which a finger is presented at the time of authentication. The interface may be any shape as long as the finger 1 is presented at the time of authentication.

A light source 23 is provided below the finger rests 25. The light source 23 irradiates the infrared light with the finger 1. The light source 23 emits light using the optical axis 231 in a direction substantially parallel to the imaging direction 320 of the imaging device 29. In addition, the imaging direction 320 is the optical axis direction which the imaging device 29 picks up.

In this explanatory drawing, four light sources 23 are provided in the lower part of each finger holder 25 in a direction substantially perpendicular to the longitudinal direction of the finger 1. As long as the light source 23 can irradiate the finger 1 with sufficient intensity, any number may be sufficient.

However, since the plurality of light sources 23 are provided side by side in a direction substantially perpendicular to the longitudinal direction of the finger 1, the entire finger 1 can be irradiated with the same brightness. Moreover, the width | variety of the longitudinal direction of the finger 1 of the input device 2 can be made small. Further, the plurality of light sources 23 are not provided side by side, and the same is true even if one light source 23 having an elongate shape is provided in a direction substantially perpendicular to the length direction of the finger.

In addition, the CPU 11 of the authentication processing unit 10 controls the light amount of the infrared light emitted by the light source 23 by executing the light amount control program 122. For example, the authentication processing unit 10 weakens the amount of light when the joint portion is placed on the finger rest 25. In addition, when the thick portion of the finger 1 is placed on the finger rest 25, the amount of light is increased.

The authentication processing part 10 may control all the light sources 23 to the same light quantity. In this case, the authentication processing unit 10 may control the light source 23 to one current. Therefore, the authentication system can be created at low cost.

In addition, the authentication processing unit 10 may control each light source 23 to a different amount of light. In this case, the authentication processing unit 10 controls the light source 23 to a plurality of different currents. Therefore, the cost of the authentication system is increased. However, since each light source 23 emits light with an appropriate amount of light, the imaging device 29 can pick up a clear image with little unevenness in brightness.

In addition, the authentication processing unit 10 has a different amount of light from the light source 23 provided in the finger holder 25 on the root side of the finger 1 and the light source 23 provided in the finger holder 25 on the fingertip side. You may control. In this case, the authentication processing unit 10 may control the light source 23 with two currents. Therefore, the authentication system can be created at low cost. In addition, the imaging device 29 can pick up a clear image with little unevenness in brightness.

In addition, a plurality of light sources 23 may be provided side by side in the longitudinal direction of the finger 1.

In addition, a plurality of light sources 23 may be arranged in a plane shape. In this case, the authentication processing unit 10 increases the light amount of the light source 23 far from the opening 30 and weakens the light amount of the light source 23 close to the opening 30. Thereby, the imaging device 29 can image the clear image with few unevenness of brightness.

The acryl plate 34 is provided in the opening part 30. The acrylic plate 34 is a material transparent to infrared light. The acrylic plate 34 prevents foreign substances including fingers and dust from entering the input device 2.

Light blocking members 32 are provided on both sides of the upper portion of the opening 30. The light blocking member 32 prevents intrusion of external light into the opening 30. For example, the light blocking member 32 is provided to cover both sides of the finger 1.

In addition, when the influence of external light is small, the light shielding member 32 is unnecessary. In addition, even when the upper part of the input device 2 needs a planar structure, the light shielding member 32 is unnecessary.

An imaging device 29 and an infrared transmission filter 27 are provided inside the input device 2.

The infrared transmission filter 27 is provided between the acrylic plate 34 and the imaging device 29. In addition, the infrared transmission filter 27 transmits only infrared light.

The imaging device 29 captures the infrared light that has passed through the opening 30, the acrylic plate 34, and the infrared transmission filter 27 from the outside of the input device 2. In addition, the imaging device 29 is provided directly below the opening 30.

In addition, a mirror or the like may be provided inside the input device 2. In this case, the imaging device 29 can be provided in any position and in any direction. Thereby, the input device 2 can make height low. This is because the distance between the opening 30 and the imaging device 29 can be adjusted by changing the path of the infrared light entering from the opening 30 to a mirror or the like.

In addition, a planar light receiving element may be provided in the opening portion 30. In addition, the light receiving element detects infrared light. In this case, the input device 2 can be made flat because the acrylic plate 34, the infrared transmission filter 27, and the imaging device 29 can be omitted.

The processing of the input device 2 will be described below.

First, a user requesting authentication presents the finger 1 on the upper portion of the finger holder 25. Then, the light source 23 irradiates the infrared light to the finger 1. This infrared light scatters in all directions inside the fingers. Therefore, a part of the infrared light scattered inside the finger reaches the upper vicinity of the opening part 30. In addition, a part of the infrared light reaching the upper vicinity of the opening proceeds to the outside of the finger 1.

Then, the infrared light that has traveled outside of the finger 1 reaches the imaging device 29 through the opening 30, the acrylic plate 34, and the infrared transmission filter 27. The imaging device 29 picks up the infrared light that has arrived.

The infrared light picked up by the imaging device 29 is transmitted from the inside of the finger 1 to the surface of the palm side of the finger 1. For this reason, the infrared light picked up by the imaging device 29 includes a weak portion that is attenuated by passing through the finger vein and a strong portion that is not attenuated by passing through the portion without the finger vein. That is, the infrared light picked up by the imaging device 29 includes the difference in contrast by the finger veins.

Therefore, the imaging device 29 can acquire the image of the finger vein pattern of the partial region (image part) of the finger 1 which is located directly above the opening 30 by imaging this infrared light.

The opening part 30 of the input device 2 of this embodiment narrows the width | variety of the longitudinal direction of a finger. Accordingly, the user moves the finger 1 in the longitudinal direction of the finger 1 in a state where the finger 1 is placed on the upper portion of the finger holder 25. At this time, the imaging device 29 of the input device 2 continuously picks up the image to be captured. And the authentication processing part 10 acquires the whole image of the finger vein pattern of the finger 1 by combining the several image image picked up by the imaging device 29. FIG.

In addition, it is desired that the imaging device 29 of the input device 2 satisfies the following optical conditions in order to clearly capture the image of the finger vein pattern of the portion to be photographed.

One is that the imaging device 29 does not image the infrared light reflected from the skin surface of the finger 1. Another is that the imaging device 29 does not image the scattered infrared light without reaching the depth where the finger vein exists.

If the optical condition is not satisfied, infrared light that does not include the information of the finger vein pattern will lower the contrast of the finger vein pattern. In addition, the image of the finger vein pattern contains unnecessary information such as wrinkles on the surface of the skin of the finger 1 and becomes unclear.

In order to satisfy the optical condition, the finger holder 25 is installed between the light source 23 and the opening 30. In addition, the finger holder 25 is made of an opaque material against infrared light.

The light source 23 emits infrared light with divergence (directivity). Therefore, if the finger rest 25 is a material transparent to infrared light, the infrared light from the light source 23 will directly reach the to-be-photographed part above the opening part 30. And the infrared light which has reached the part to be photographed directly does not satisfy the optical condition because it is reflected from the skin surface of the part to be captured and reaches the imaging device 29. Therefore, the finger rest 25 should be a material opaque to infrared light.

In addition, the inner wall of the input device 2, the filter 27, the imaging device 29, and the acrylic plate 34 are preferably made of a material that does not reflect infrared light. This is because the infrared light traveling from the inside of the finger 1 to the outside is reflected inside the input device 2 so as not to reach the surface of the finger 1 again.

In addition, in order to satisfy the optical condition, the finger rest 25 covers the upper part of the opening part 30 side of the light source 23 more than half. As a result, the imaging device 29 is almost unaffected by scattered infrared light (for example, infrared light scattered near the surface of the finger 1) without reaching the depth where the finger vein exists. An image of a pattern can be picked up.

This reason is explained below.

4A is an explanatory diagram of the effect of the shape of the finger rest 25 of the first embodiment of the present invention.

In this explanatory drawing, the finger rests 25 cover the upper part of the opening part 30 side of the light source 23 more than half. As a result, the infrared light from the light source 23 is directed to the opposite side of the opening 30.

The finger holder 25 may be provided so that the emission of infrared light from the light source 23 does not include the imaging direction 320. That is, the finger rest 25 is installed so that all components of the infrared light from the light source 23 face the opposite side of the opening part 30. In addition, the divergence of the infrared light from the light source 23 is in the range between the boundary lines 322. In addition, the imaging direction 320 is the optical axis direction which the imaging device 29 picks up.

In the present embodiment, the light source 23 emits light with an optical axis in a direction substantially parallel to the imaging direction 320.

Next, the path of the infrared light in this case will be described.

First, the infrared light from the light source 23 reaches the finger 1. Then, a part of the infrared light which has reached the finger 1 is reflected on the skin surface of the finger 1. In addition, part of the infrared light proceeds to the inside of the finger 1.

In addition, the infrared light reflected from the skin surface of the finger 1 does not reach the upper portion of the opening 30 because it is blocked by the finger holder 25.

A portion 326 of the infrared light traveling into the interior of the finger 1 is scattered without reaching the depth where the finger vein 62 is present. In addition, part of the infrared light 324 scatters after reaching the depth where the finger vein 62 exists.

The scattered infrared light 326 also changes the direction of travel without reaching the depth where the finger vein 62 is present. However, there is very little infrared light reaching the upper portion of the opening 30 among the infrared light 326. This is because most of the components of the infrared light directed to the finger 1 are directed to the opposite side of the opening 30.

Part of the scattered infrared light 324 is absorbed by the finger vein 62 after the finger vein 62 has reached its present depth. In addition, a part of the infrared light 324 reaches the upper portion of the opening 30. As a result, the infrared light 324 reaches the upper portion of the opening 30 while retaining information of the finger vein pattern.

Therefore, the imaging device 29 can image the finger vein pattern by imaging the infrared light 324. At this time, the imaging device 29 minimizes the influence of the scattered infrared light 326 and the infrared light reflected from the skin surface of the finger 1 without reaching the depth where the finger vein 62 exists. An image of a pattern can be picked up.

4B is an explanatory view of the effect according to the shape of the finger rest 25 of the first embodiment of the present invention.

In the explanatory drawing, unlike the finger rest 25 of the present embodiment, the finger rest 251 does not have a light blocking member on the upper portion of the light source 23. By explaining the path of infrared light in the case of this finger holder 251, it contrasts with the finger holder 25 of this embodiment.

In this case, the emission of the infrared light from the light source 23 is a range between the boundary lines 327 and includes the imaging direction 320. That is, the infrared light from the light source 23 contains the component which faces the opening part 30 side.

Next, the path of the infrared light in this case will be described.

The path of infrared light is the same as that of infrared light (FIG. 4A) in the case of finger holder 25, except for the path of infrared light 326 scattered without reaching the depth where finger vein 62 is present. . The description of the same path of infrared light is omitted.

In the case of this explanatory drawing, the infrared light from the light source 23 contains the component which faces the opening part 30 side. Thus, a portion of the scattered infrared light 326 reaches the top of the opening 30 without reaching the depth where the finger vein 62 is present.

That is, when the finger rest 251 does not cover the upper part of the light source 23, the imaging device 29 is scattered without reaching the depth where the finger vein 62 exists at the time of imaging the image of a finger vein pattern. Affected by external light 326. Therefore, the imaging device 29 cannot image an image of a finger vein pattern clearly.

On the other hand, when the finger rest 25 covers the upper part of the opening part 30 side of the light source 23 or more, the imaging device 29 will scatter the infrared light scattered without reaching the depth where the finger vein 62 exists. Since it is hardly influenced by 326, the image of the finger vein pattern can be captured clearly.

The input device 2 of this embodiment is a sweep type authentication device. Accordingly, the user moves the finger 1 in the longitudinal direction of the finger 1 in a state where the finger 1 is placed on the upper portion of the finger holder 25. However, when the user moves the finger 1, it is assumed that the finger 1 floats from the finger holder 25. Also in this case, the finger rest 25 covers the upper part of the opening part 30 side of the light source 23 more than half, and the imaging device 29 can image an image of a finger vein pattern clearly.

This reason is explained below.

FIG. 5A is an explanatory view of the effect of the shape of the finger rest 25 of the first embodiment of the present invention. FIG.

In this explanatory drawing, the finger rests 25 cover the upper part of the opening part 30 side of the light source 23 more than half. As a result, the infrared light from the light source 23 is directed to the opposite side of the opening 30.

The finger holder 25 may be provided so that the emission of infrared light from the light source 23 does not include the imaging direction 320. That is, the finger rest 25 is installed so that all components of the infrared light from the light source 23 face the opposite side of the opening part 30. In addition, the divergence of the infrared light from the light source 23 is in the range between the boundary lines 322. In addition, the imaging direction 320 is the optical axis direction which the imaging device 29 picks up.

Next, the path of the infrared light in this case will be described.

First, the infrared light from the light source 23 reaches the finger 1. Then, the portion 342 of the infrared light reaching the finger 1 reflects off the surface of the finger 1. In addition, part of the infrared light 324 proceeds to the inside of the finger 1.

In addition, the path of the infrared light 324 which advanced to the inside of the finger 1 is the same as the path of the infrared light demonstrated by FIG. 4A. Therefore, description is omitted.

On the other hand, the infrared light 342 reflected from the surface of the finger 1 changes the traveling direction. However, there is very little infrared light reaching the upper portion of the opening 30 among the infrared light 342. This is because the infrared light reaching the finger 1 is directed toward the opposite side of the opening 30. That is, since most components of the infrared light 342 reflected from the surface of the finger 1 advance in the opposite direction to the opening portion 30.

5B is an explanatory view of the effect according to the shape of the finger rest 25 of the first embodiment of the present invention.

In the explanatory diagram, the finger rest 251 does not have a light blocking member on the upper portion of the light source 23 unlike the finger rest 25 of the present embodiment. By explaining the path of infrared light in the case of this finger holder 251, it contrasts with the finger holder 25 of this embodiment.

In this case, the emission of the infrared light from the light source 23 is a range between the boundary lines 327 and includes the imaging direction 320. That is, the infrared light from the light source 23 contains the component which faces the opening part 30 side.

Next, the path of the infrared light in this case will be described.

The path of infrared light is the same as the path of infrared light (FIG. 5A) in the case of the finger holder 25 except for the infrared light 342 reflected from the surface of the finger 1. Therefore, description of the same path of infrared light is omitted.

In the case of this explanatory drawing, the infrared light from the light source 23 contains the component which faces the opening part 30 side. Therefore, a part of the infrared light 342 reflected from the surface of the finger 1 reaches the upper portion of the opening 30.

That is, when the finger rest 251 does not cover the upper part of the light source 23, the imaging device 29 influences the infrared light 342 reflected from the surface of the finger 1 at the time of imaging the image of a finger vein pattern. Will receive. Therefore, the imaging device 29 cannot image an image of a finger vein pattern clearly.

On the other hand, if the finger rest 25 covers the upper part of the opening part 30 side of the light source 23 more than half, the imaging device 29 will hardly affect the influence of the infrared light 342 reflected from the surface of the finger 1. Since it is not received, the image of the finger vein pattern can be captured clearly.

That is, the finger rest 25 needs to cover the upper part of the light source 23 in order to keep the divergence of the infrared light from the light source 23 away from the opening 30.

Further, the width of the finger rests 25 may be sufficiently widened without covering the upper portion of the light source 23. In this case, the input device 2 is enlarged, but the imaging device 29 is reflected by the scattered infrared light 326 and the skin surface of the finger 1 without reaching the depth where the finger vein 62 exists. An image of a finger vein pattern can be picked up with very little influence of external light.

Next, the image of the finger vein pattern picked up by the imaging device 29 will be described.

Fig. 6 is an explanatory diagram showing the relationship between the distance from the light source 23 and the luminance value of the finger vein pattern image according to the first embodiment of the present invention.

The graph shown in this explanatory diagram shows the relationship between the distance from the light source 23 and the luminance value of the finger vein pattern image.

First, the case where the light amount of the infrared light which the light source 23 emits does not change is demonstrated.

If the distance from the light source 23 is close, the luminance value of the image is large. As the distance from the light source 23 increases, the luminance value of the image decreases. In addition, when the distance from the light source 23 is far from the light source 23 at a position close to each other, the luminance value of the image decreases rapidly. On the other hand, even if the distance from the light source 23 is far from the light source 23 at a position far away from the light source 23, the luminance value of the image gradually decreases.

The luminance value is divided into one of the high luminance region 184, the visible region 186, or the low luminance region 188.

If the luminance value is within the range of the high luminance region 184, the authentication processing unit 10 cannot obtain information of the finger vein pattern from the image. This is because light is saturated in the image.

If the luminance value is within the range of the visible region 186, the authentication processing unit 10 can acquire the information of the finger vein pattern from the image.

If the luminance value is within the range of the low luminance region 188, the authentication processing unit 10 cannot obtain information of the finger vein pattern from the image. This is because light is too weak in the image.

In other words, the visible region 186 is a range in which the imaging device 29 can detect the intensity of light. In addition, the high luminance region 184 and the low luminance region 188 are ranges in which the imaging device 29 cannot detect the intensity of light.

Next, when the light amount of the infrared light emitted by the light source 23 is strengthened, the curve representing the luminance value of the image shifts to the method on the right side. That is, when the light quantity of the light source 23 is made strong, the position used as the visible area 186 will be far from the light source 23.

On the other hand, when the light amount of the infrared light emitted by the light source 23 is weakened, the curve representing the luminance value of the image moves in the lower left method. That is, when the light amount of the light source 23 is made weak, the position used as the visible region 186 approaches the light source 23.

This explanatory drawing is a luminance value of an image by the light source 23 on the root side of the finger 1. In addition, the luminance value of the image by the light source 23 by the fingertip side becomes a curve which inverted the curve of this explanatory drawing left and right.

And the luminance value of the image by the light source 23 of the root side of the finger 1, and the light source 23 of the finger tip side becomes a curve which overlapped these two curves.

In the present embodiment, the width of the opening 30 is sufficiently narrower than the visible region 186. Therefore, the whole area | region of the opening part 30 can be included in the visible area 186 by adjusting the light quantity of the infrared light which the light source 23 emits.

In addition, the light source 23 may be provided only at either the source side or the finger tip side of the finger 1. Even in this case, since the width of the opening 30 is sufficiently narrower than that of the visible region 186, the entire region of the opening 30 can be included in the visible region 186. The finger holder 25 may or may not be installed on the side not having the light source 23.

However, since the finger rest 25 is provided also in the side which does not have a light source, the shift | offset | difference of the movement of the finger 1 can be suppressed. On the other hand, the input device 2 can be further miniaturized by omitting the finger rest 25 and the light source 23 on either the root side or the finger tip side of the finger 1.

In addition, when the width | variety of the opening part 30 cannot be included in the visible area 186, the light quantity of the infrared light which the light source 23 emits continuously changes. The imaging device 29 picks up an image for each light amount. And the authentication processing part 10 acquires the whole image of the width | variety of the opening part 30 by combining these images picked up by the imaging device 29. As shown in FIG.

7 is a flowchart of the authentication processing of the authentication processing unit 10 according to the first embodiment of the present invention.

First, the authentication processing unit 10 performs finger detection processing (S100) to determine whether or not the finger 1 is placed on the finger holder 25 (S110).

For example, it is determined whether or not the finger 1 is placed on the finger rest 25 using information from a contact sensor, a temperature sensor, an electrical resistance sensor, a dielectric constant sensor, or the like. In addition, the image picked up by the imaging device 29 may be used to determine whether or not the finger 1 is placed on the finger rest 25.

Specifically, the case where the image picked up by the imaging device 29 is used will be described.

In this case, since the sensor is unnecessary, the authentication system can be constructed at low cost.

In this case, the light source 23 lights up at a constant cycle. In addition, the imaging device 29 picks up an image at a cycle shorter than a cycle of turning on the light source 23. The imaging device 29 then transmits the captured image to the authentication processing unit 10.

First, the authentication processing unit 10 receives an image from the imaging device 29. Next, the luminance value of the received image is obtained. Next, the amount of change in the luminance value of the image is obtained by comparing the luminance values of the images continuously received. Then, it is determined whether or not the finger 1 is placed on the finger rest 25 based on the amount of change in the luminance value of the obtained image.

Specifically, when the amount of change in the luminance value of the image is smaller than the threshold value, it is determined that the finger 1 is not placed on the finger rest 25. This is because the infrared light emitted from the light source 23 does not reach the imaging device 29 unless the finger 1 is placed on the finger rest 25.

On the other hand, when the amount of change in the luminance value of the image is equal to or greater than the threshold value, it is determined that the finger 1 is placed on the finger rest 25. This is because if the finger 1 is placed on the finger rest 25, the infrared light emitted from the light source 23 scatters inside the finger 1 to reach the imaging device 29.

If it is determined that the finger 1 is not placed on the finger holder 25, the process returns to step S100 since it is not necessary to perform the authentication process.

On the other hand, when it is determined that the finger 1 is placed on the finger rest 25, the light amount control process is performed (S120).

Specifically, the light amount of the light source 23 is controlled so that the luminance value of the image picked up by the imaging device 29 approaches the target value. The target value is the luminance value at which the difference in contrast between the vein portion and other tissue portions is greatest. The target value is a constant value regardless of the shape and size of the finger.

Here, the case where the authentication processing part 10 controls the light source 23 of the finger tip side, and the light source 23 of the root side of the finger 1 separately is demonstrated.

The authentication processing unit 10 receives an image from the imaging device 29. Next, the mean luminance value of the other side of the fingertip of the received image and the mean luminance value of the other side of the root side of the finger 1 of the corresponding image are obtained.

Next, the light amount of the light source 23 is controlled according to the obtained average brightness value. Specifically, the light amount of the light source 23 on the fingertip side is controlled so that the mean luminance value on the other side of the fingertip is close to the target value. Further, the amount of light of the light source 23 on the root side of the finger 1 is controlled so that the mean luminance value on the other side of the finger 1 approaches the target value.

In addition, the authentication processing unit 10 increases or decreases the light amount of the light source 23 while feeding back the luminance value of the image, thereby bringing the luminance value closer to the target value. In this case, the value which increases or decreases the light quantity of the light source 23 may be a fixed value or may be changed according to the procedure. Further, the authentication processing unit 10 may estimate the amount of light that brings the luminance value of the image closer to the target value based on the characteristics of the imaging device 29, and cause the light source 23 to emit the estimated amount of light.

Next, the feature extraction process (S130) is performed. Note that the feature extraction processing will be described later with reference to FIGS. 8A, 8B, and 8C, but extracts feature data from the image picked up by the imaging device 29.

Next, the feature data joining process (S140) is performed. Note that the feature data conjugation process will be described later with reference to Fig. 9, but the extracted feature data and the past feature data are conjoined.

Next, it is determined whether the size of the combined feature data is equal to or larger than the threshold value (S150). The threshold is also the size of the feature data needed for matching.

Specifically, in the feature data joining process (S140), the movement amount of the finger 1 can be obtained. Then, it is determined whether the size of the feature data is equal to or larger than the threshold value based on the obtained movement amount of the finger 1.

If the size of the feature data is smaller than the threshold value, the feature matching processing cannot be performed, and the flow returns to step S120.

On the other hand, if the size of the feature data is equal to or larger than the threshold value, the feature matching process (S160) is performed.

In addition, in step S150, you may determine whether the movement speed of the finger 1 was slower than the threshold value. In this case, if the size of the feature data is equal to or larger than the threshold value and the moving speed of the finger 1 is lower than the threshold value, the feature matching process (S160) is performed.

In addition, since the movement amount of the finger 1 differs according to the difference in the finger lengths, the finger 1 may move even if the size of the feature data exceeds the threshold. In this case, the feature data is continuously taken until the finger 1 stops or just before the stop. Then, the feature collation process (S160) is started when the feature data is acquired up to the maximum size. As a result, the recognition rate can be further increased.

Specifically, the feature data joined in step S140 and the authentication data stored in the storage device 14 are collated.

For example, the similarity between the characteristic data and the authentication data is calculated. And if the calculated similarity is more than a threshold, it authenticates as a person corresponding to the said authentication data.

Then, the authentication process ends.

In addition, there is a possibility that distortion occurs in the feature data joined by the feature data joining process (S140). In this case, the authentication processing unit 10 performs the feature matching processing (S160) by using a matching method in which distortion is considered.

The contrasting method considering distortion is a method of contrasting while enlarging or reducing an image, and a method of comprehensively determining a result of independently collating in each region by dividing the image into a plurality of images. In the method of collating while enlarging or reducing the image, the distortion in the moving direction of the finger 1 is appropriately corrected by increasing the stretching ratio in the longitudinal direction of the finger 1.

Hereinafter, the feature extraction processing (S130) of the authentication processing unit 10 will be described.

8A is an explanatory diagram of a finger vein 62 captured by the imaging device 29 of the first embodiment of the present invention.

Finger veins 62 are distributed throughout finger 1. The imaging device 29 picks up the presented finger 1 of the opening 30. That is, the imaging device 29 picks up the finger vein 62 included in the range of the opening 30.

8B is an explanatory diagram of an image 64 captured by the imaging device 29 of the first embodiment of the present invention.

The image 64 is an image picked up by the imaging device 29. The finger 1 and the finger vein 62 included in the range of the opening 30 are projected on the image 64.

The authentication processing part 10 extracts the range of the opening part 30 from the image 64 picked up by the imaging device 29.

The range of the opening portion 30 may be set in advance, or may be automatically determined by the authentication processing unit 10.

Here, the method by which the authentication processing part 10 measures the range of the opening part 30 automatically is demonstrated.

The authentication processing part 10 determines the range of the opening part 30 by the difference of the brightness | luminance on the image image | photographed by the imaging device 29. FIG. However, this image is taken as the image which is imaged in the state where the light source 23 emits light and the finger 1 is placed on the finger rest 25.

Next, the authentication processing part 10 extracts the image of a finger vein pattern from the image of the extracted opening 30 range.

Specifically, the image of the finger vein pattern is extracted using a general image processing method. Typical image processing methods include a dark line tracking method, a line pattern emphasis method by filter processing, or a line pattern extraction method based on the curvature of the luminance profile curve of an image.

In addition, the authentication processing unit 10 may extract a finger vein pattern image after performing a finger outline detection process on the image of the extracted range of the opening 30. The finger outline detection process detects the outline of the finger 1 by distinguishing the finger area from the other areas. The authentication processing unit 10 can extract the image of the finger vein pattern with high accuracy by performing the finger outline detection process in advance.

Specifically, the outline of the finger 1 is detected using the method of general image processing. Common methods of image processing include edge emphasis processing or contour tracking processing.

For example, the authentication processing unit 10 controls the light source 23 to blink. At this time, the imaging device 29 captures an image when the light source 23 is turned on and an image when the light source 23 is turned off and inputs it to the authentication processing unit 10.

The authentication processing unit 10 obtains respective luminance values from the image when the input light source 23 is turned on and the image when the light source is turned off. The area where the difference between the luminance value of the image when the light source 23 is turned on and the luminance value when the light source 23 is turned off is detected as a finger region. In this way, the authentication processing unit 10 can stably detect the outline of the finger 1 by comparing the image when the light source 23 is turned on and the image when the light source 23 is turned off.

In addition, the contour of the finger 1 may be detected by the following method. The imaging device 29 picks up an image in a state where the light amount of the light source 23 on one side of the finger 1 is strong and the light amount on the opposite side is weak. Next, the imaging device 29 picks up an image of the state where the intensity of the light amount of the light source 23 is replaced. The imaging device 29 inputs the captured images to the authentication processing unit 10.

The authentication processing unit 10 detects as a finger area an area where the difference in luminance values of these input images is large.

Next, the authentication processing unit 10 converts the extracted image of the finger vein pattern into feature data.

8C is an explanatory diagram of the feature data 66 converted by the authentication processing unit 10 according to the first embodiment of the present invention.

The feature data 66 is information used for collation with the collation data stored in the storage device 14.

The feature data 66 shows the correspondence between the position (x coordinate) on the image and the luminance value. In addition, the x-axis is a direction substantially perpendicular to the longitudinal direction of the finger 1. In addition, the characteristic data 66 of this explanatory drawing relates to the area | region 65 on the image 64 (FIG. 8B).

The feature data 66 has a plurality of local points 68. The minimum point 68 is the location of the finger vein. This is because the blood in the finger vein absorbs the infrared light from the light source 23.

The feature data may be an image of a finger vein pattern used for template matching, or may be structural information of a line segment. The structural information of the line segment includes information about branching points and end points of the finger veins, and information on the finger veins is abstracted.

Hereinafter, the characteristic data joining process (S140) of the authentication processing unit 10 will be described.

9 is an explanatory diagram of characteristic data joining processing (S140) of authentication processing unit 10 according to the first embodiment of the present invention.

In this explanatory drawing, the case of the image of the finger vein pattern in which the feature data is used for template matching will be described as an example. The same is true even if the feature data is other information including the structure information of the line segment and the like.

The authentication processing unit 10 joins the feature data extracted by the feature extraction process (S130). Here, the case where the authentication processing unit 10 joins the feature data 80 extracted from the image 64 of the frame N to the feature data 82 extracted from the image from the frame 1 to the frame N-1 will be described. Here, the frame N shows the procedure of the image picked up by the imaging device 29. In addition, the image capturing apparatus 29 captures the first image of the finger 1 as frame 1.

First, the authentication processing unit 10 overlaps each other on the feature data 82 extracted from the image up to the frame N-1 while moving the position of the feature data 80 extracted from the image 64 of the frame N.

Next, the authentication processing unit 10 obtains a degree of agreement between the feature data 80 of the frame N and the feature data 82 up to the frame N-1 at each position where the feature data 80 is moved. Next, the deviation amount of the finger 1 is calculated | required based on the agreement degree of the obtained characteristic data. The position shifted by the deviation amount from the position of frame N-1 is determined as the position of the feature data 80 extracted from the image 64 of frame N. As shown in FIG.

In addition, the deviation amount of the finger 1 may be obtained using a method of observing wrinkles on the surface of the finger 1, a method of observing the outline of the finger 1, or the like. By using these methods together, the amount of deviation of the finger 1 can be calculated with high precision.

Here, the authentication processing part 10 memorize | stores the coordinate 92 of the upper left of the position 88 which joined the characteristic data up to frame N-1. The authentication processing unit 10 stores the feature data 80 of the frame N such that the coordinate 90 of the upper left of the position of the feature data 80 of the frame N fits within a predetermined range centered on the coordinate 92. Move position

In this case, since the authentication processing part 10 limited the position which moves the characteristic data 80, the burden of calculation of the deviation amount of the finger 1 can be reduced.

In addition, the image of frame N and the image of frame N-1 are the images picked up continuously, and there is no big change in a position. Therefore, even if the authentication processing part 10 limits the position which moves the characteristic data 80, a problem does not arise.

When determining the position of the feature data 80 of the frame N, the authentication processing unit 10 joins the feature data 80 of the frame N with the feature data 82 up to the frame N-1.

Specifically, the feature data 80 of the frame N and the feature data 82 up to the frame N-1 are bonded together using a general image bonding method. A common image joining method is a method of overwriting a feature pattern, a method of taking an average value of a feature pattern, or a method of taking a majority of feature patterns.

As described above, the authentication processing unit 10 can acquire the vein pattern of the entire finger 1 by performing the bonding process (S140).

(2nd embodiment)

In the second embodiment of the present invention, the input device 2 includes a reflected light source.

The structure of the authentication system of 2nd Embodiment of this invention is the same as that of the authentication system (FIG. 1) of 1st Embodiment except the input device 2. As shown in FIG. In addition, the process of the authentication system of 2nd Embodiment of this invention is the same as that of the authentication system (FIG. 7 etc.) of 1st Embodiment. The same configuration and processing will be omitted.

10 is a side view of the input device 2 according to the second embodiment of the present invention.

The input device 2 of the second embodiment includes a reflected light source 102. The other configuration is the same as that of the input device (FIGS. 3A, 3B, and 3C) of the first embodiment. The same configuration is given the same number and the description is omitted.

In the explanatory drawing, the reflected light source 102 is provided near the imaging device 29 inside the input device 2. In addition, the reflection light source 102 is provided toward the direction of the opening part 30. Therefore, the reflected light source 102 irradiates infrared light to the to-be-photographed part of the finger 1.

In addition, as long as the reflected light source 102 can irradiate infrared light to the to-be-photographed part of the finger 1, you may be provided in the arbitrary place inside the input device 2. As shown in FIG. In addition, the reflected light source 102 may be provided in plurality inside the input device 2.

When the reflected light source 102 irradiates the to-be-photographed part of the finger 1, the imaging device 29 images the infrared light reflected from the skin of the surface of the finger 1. That is, the imaging device 29 can image an image of the surface of the finger 1.

The authentication processing part 10 can acquire various information using the image of the surface of the finger 1 imaged by the imaging device 29.

For example, the authentication processing unit 10 obtains the reflectance of the object presented to the finger rest 25 from the image picked up by the imaging device 29. Then, based on the obtained reflectance, it can be determined whether or not the presented object is the finger 1.

In addition, the authentication processing unit 10 can extract the wrinkle information on the surface of the finger 1 from the image picked up by the imaging device 29. And based on the extracted wrinkle information, the movement amount of the finger 1 can be calculated | required.

In addition, when the light source 23 is turned off and the reflected light source 102 is lit, the imaging device 29 picks up an image of the surface of the finger 1. On the other hand, when the light source 23 is turned on and the reflected light source 102 is turned off, the imaging device 29 picks up an image of the finger vein pattern.

The input device 2 of this embodiment is a swept finger vein authentication device. Thus, the finger 1 moves on the finger holder 25.

Therefore, the authentication processing unit 10 turns on the reflected light source 102 and the light source 23 alternately. The imaging device 29 captures the finger 1 in accordance with the timing of the lighting of the reflected light source 102 and the light source 23. Then, the imaging device 29 can alternately image the image of the surface of the finger 1 and the image of the finger vein pattern.

In addition, the reflected light source 102 may be used in the finger detection process (step S100 of FIG. 7). In this case, the reflected light source 102 lights up at a constant cycle. In addition, the imaging device 29 picks up an image at a cycle shorter than a cycle of turning on the reflected light source 102. The imaging device 29 inputs the captured image to the authentication processing unit 10.

The authentication processing unit 10 obtains the luminance value of the input image. Next, the amount of change in the luminance value of the image is obtained by comparing the luminance values of the images continuously received. Then, it is determined whether or not the finger 1 is placed on the finger rest 25 based on the amount of change in the luminance value of the obtained image.

Specifically, when the amount of change in the luminance value of the image is smaller than the threshold value, it is determined that the finger 1 is not placed on the finger rest 25.

On the other hand, if the amount of change in the luminance value of the image is greater than or equal to the threshold value, it is determined that the finger 1 is placed on the finger rest 25.

As described above, the authentication processing unit 10 can perform the finger detection process (step S100 in FIG. 7) using the reflected light source 102.

The authentication system of the present embodiment can reduce power consumption by performing a finger detection process using the reflected light source 102 instead of the light source 23. This is because the authentication processing unit 10 can detect the finger by irradiating the finger 1 with the infrared light weaker than the light source 23 by the reflected light source 102.

(Third embodiment)

In the third embodiment of the present invention, the light source 23 is inclined.

The structure of the authentication system of 3rd Embodiment of this invention is the same as that of the authentication system (FIG. 1) of 1st Embodiment except the input device 2. As shown in FIG. In addition, the process of the authentication system of 3rd Embodiment of this invention is the same as that of the authentication system (FIG. 7 etc.) of 1st Embodiment. The same configuration and processing will be omitted.

11A is a plan view of the input device 2 according to the third embodiment of the present invention. FIG. 11: B is explanatory drawing of the light source 23 of the input device 2 of 3rd Embodiment of this invention. 11C is a front view of the input device 2 according to the third embodiment of the present invention.

The configuration of the input device 2 of the third embodiment is the same as that of the input device (FIGS. 3A, 3B, and 3C) of the first embodiment except for the light source 23 and the finger rest 25. The same configuration is given the same number and the description is omitted.

The light source 23 emits infrared light with divergence (directivity). In addition, the light source 23 is provided inclined to the opposite side of the opening part 30.

The light source 23 is installed at an angle of 60 degrees from the imaging direction 320 of the imaging device 29, for example. That is, the light source 23 emits light by making the optical axis 231 the 60 degree tilt direction from the imaging direction 320 of the imaging device 29. In addition, the imaging direction 320 is the optical axis direction which the imaging device 29 picks up. As a result, the infrared light from the light source 23 is directed to the opposite side of the opening 30.

The finger holder 25 is provided so that the emission of the infrared light from the light source 23 does not include the imaging direction. That is, the finger rest 25 is installed so that all components of the infrared light from the light source 23 face the opposite side of the opening part 30. In addition, the divergence of the infrared light from the light source 23 is in the range between the boundary lines 322.

In addition, the finger rest 25 of this embodiment does not need to cover the upper part of the light source 23 to half. This is because the light source 23 is inclined with respect to the imaging direction. In addition, the finger rest 25 does not need to cover the upper part of the light source 23 depending on the emission of infrared light from the light source 23.

In addition, in this embodiment, the infrared light emitted from the light source 23 enters the finger 1 at a position far from the opening 30 compared with the first embodiment. This also has the advantage that the luminance value of the image picked up by the imaging device 29 becomes uniform.

(4th embodiment)

In the fourth embodiment of the present invention, the finger rest 25 includes a recess.

The structure of the authentication system of 4th Embodiment of this invention is the same as that of the authentication system (FIG. 1) of 1st Embodiment except the input device 2. As shown in FIG. In addition, the process of the authentication system of 4th Embodiment of this invention is the same as that of the authentication system (FIG. 7 etc.) of 1st Embodiment. The same configuration and processing will be omitted.

12 is a front view of the input device 2 according to the fourth embodiment of the present invention.

The configuration of the input device 2 of the fourth embodiment is the same as that of the input device (FIGS. 3A, 3B, and 3C) of the first embodiment, except for the finger rest 25. The same configuration is given the same number and the description is omitted.

The finger holder 25 has a recess 142 on the surface in contact with the finger 1. The recessed portion 142 extends in the longitudinal direction of the finger 1. Since the recess 142 does not press the finger 1, the recess 142 pushes the blood flow inside the finger 1.

Assume that the user moves the finger 1 while pushing the finger 1 to the finger holder 25 with more pressure than necessary. In this case, when the finger rest 25 does not have the recessed part 142, blood flows by the pressure with the finger rest 25, and the blood of the to-be-photographed surface of the finger 1 is depleted. For this reason, the finger vein pattern becomes unclear in the image picked up by the imaging device 29.

On the other hand, when the finger rest 25 has a recess 142, blood flows through the recess 142. Therefore, even if the user pushes the finger 1 on the finger holder 25 with a pressure higher than necessary, the imaging device 29 can clearly capture an image of the finger vein pattern.

(5th embodiment)

In the fifth embodiment of the present invention, the finger rest and the light blocking member are separately included.

The structure of the authentication system of 5th Embodiment of this invention is the same as that of the authentication system (FIG. 1) of 1st Embodiment except the input device 2. As shown in FIG. In addition, the process of the authentication system of 5th Embodiment of this invention is the same as that of the authentication system (FIG. 7 etc.) of 1st Embodiment. The same configuration and processing will be omitted.

13 is a side view of the input device 2 according to the fifth embodiment of the present invention.

The configuration of the input device 2 of the fifth embodiment is the same as the input device (FIGS. 3A, 3B, and 3C) of the first embodiment except for the light blocking member 22 and the finger rest 28. The same configuration is given the same number and the description is omitted.

The light blocking member 22 and the finger rest 28 are provided in the input device 2 instead of the finger rest 25 of 1st Embodiment.

The finger rest 25 of the first embodiment has a function of the light blocking member because of being a material that is opaque to infrared light.

In the present embodiment, the light blocking member 22 is provided between the light source 23 and the opening 30. The light blocking member 22 is a material which is opaque to infrared light.

The finger holder 28 is provided on the opposite side of the opening 30 to the light source 23. The finger holder 28 is a stand for placing the finger 1 at the time of authentication. In this case, the finger rest 28 may be a material transparent to infrared light or may be an opaque material.

(6th Embodiment)

In the sixth embodiment of the present invention, authentication is performed without moving the finger 1.

The configuration of the authentication system of the sixth embodiment of the present invention is the same as that of the authentication system (FIG. 1) of the first embodiment except for the configuration of the input device 2. The same configuration is omitted.

14 is a side view of the input device 2 according to the sixth embodiment of the present invention.

The configuration of the input device 2 of the sixth embodiment is the same as that of the input device (FIGS. 3A, 3B and 3C) of the first embodiment except for the size of the opening 30. The same configuration is given the same number and the description is omitted.

Two finger rests 25 are provided so that the opening part 30 may be formed between them. The opening part 30 is wider in the longitudinal direction of the finger 1 than the opening part (FIG. 3A) of 1st Embodiment. The opening 30 has a width enough for the imaging device 29 to capture an image of a finger vein pattern required for authentication.

In the authentication system of the sixth embodiment, since the width of the opening 30 is wide, it is not necessary for the user to move the finger 1. Accordingly, the user can authenticate by simply placing the finger 1 on the finger holder 25.

The light quantity control process of this embodiment is demonstrated.

Fig. 15 is an explanatory diagram showing the relationship between the distance from the light source 23 and the luminance value of the finger vein pattern image according to the sixth embodiment of the present invention.

The graph shown in this explanatory diagram shows the relationship between the distance from the light source 23 and the luminance value of the finger vein pattern image. In addition, this graph is a case where the light source 23 exists in the fingertip side and the base side of the finger 1. Therefore, the graph is obtained by inverting the graph (FIG. 6) in the case where the light source 23 exists only on one side and combining them.

The luminance value is divided into one of the high luminance region 184, the visible region 186, or the low luminance region 188.

If the luminance value is within the range of the high luminance region 184, the authentication processing unit 10 cannot obtain information of the finger vein pattern from the image. This is because light is saturated in the image. If the luminance value is within the range of the visible region 186, the authentication processing unit 10 can acquire the information of the finger vein pattern from the image. If the luminance value is within the range of the low luminance region 188, the authentication processing unit 10 cannot obtain information of the finger vein pattern from the image. This is because light is too weak in the image.

In the input device 2 of the present embodiment, the width of the opening 30 is wide. Therefore, even if the authentication process part 10 adjusts the light quantity of the light source 23 of both sides, the whole area | region of the opening part 30 may not be included in the visible area 186.

In this case, the authentication processing unit 10 changes the light amount of the light source 23 at the source side of the finger 1 and the light amount of the light source 23 at the fingertip side in time series. At this time, the imaging device 29 picks up an image in each light amount. The captured image is partially at an optimum brightness. And the authentication processing part 10 synthesize | combines the image picked up by the imaging device 29, and acquires the image of the optimal brightness as a whole.

The specific processing will be described below.

First, the authentication processing unit 10 strengthens the light amount of the light source 23 on the root side of the finger 1 and weakens the light amount of the light source 23 on the fingertip side.

In this state, the imaging device 29 picks up an image. The image has the same luminance value as the graph shown in FIG. 15A. Therefore, the image becomes as shown in FIG. 16A.

Fig. 16A is an explanatory diagram of an image picked up when the light source 23 on the root side of the finger 1 of the sixth embodiment of the present invention is strong.

In the case where the light source 23 at the source side of the finger 1 is strong, the image picked up by the imaging device 29 is at the optimum brightness in the region above the fingertip side. However, in the image, light is saturated at a part of the root side of the finger 1.

Therefore, the authentication processing part 10 weakens the light quantity of the light source 23 of the source side of the finger 1, and strengthens the light quantity of the light source 23 of the fingertip side.

In this state, the imaging device 29 picks up an image. The image has the same luminance value as the graph shown in FIG. 15B. Therefore, the image becomes as shown in Fig. 16B.

16B is an explanatory diagram of an image picked up when the light source 23 on the fingertip side of the sixth embodiment of the present invention is strong.

In the case where the light source 23 on the fingertip side is strong, the image picked up by the imaging device 29 is at the optimum brightness in the above-described region on the root side of the finger 1. However, in the image, light is saturated at a portion of the fingertip side.

The authentication processing unit 10 synthesizes these two images (Figs. 16A and 16B) captured by the imaging device 29.

16C is an explanatory diagram of an image synthesized by the authentication processing unit 10 according to the sixth embodiment of the present invention.

The authentication processing unit 10 synthesizes an image of optimum brightness (Fig. 16A) in the above and other areas on the fingertip side and an image of optimum brightness (Fig. 16B) in the above and other area on the root side of the finger 1. Thereby, the authentication processing part 10 acquires the image of the optimal brightness in the whole area | region of this explanatory drawing.

In addition, the authentication processing unit 10 can acquire images of optimal brightness in the entire area by combining two or more images.

In this case, the authentication processing unit 10 gradually increases the light amount of the light source 23 on one side, and gradually weakens the light amount of the other light source 23. The imaging device 29 picks up an image in each light amount. In this image, the area of optimal brightness is gradually moved. And the authentication processing part 10 synthesize | combines the image picked up by the imaging device 29, and acquires the image of the optimal brightness as a whole.

In addition, the imaging device 29 of the authentication system of the sixth aspect images the finger 1 as a whole. Therefore, since the authentication processing unit 10 corrects the inclination of the finger 1 and removes the background, it is necessary to detect the outline of the finger 1.

The authentication processing unit 10 uses a general image processing method, and a general image processing method for detecting an outline of the finger 1 is edge emphasis or contour tracking.

In addition, the authentication processing unit 10 may detect the outline of the finger 1 by comparing a plurality of images.

Specifically, the authentication processing part 10 compares the image which hardened the light quantity of the light source 23, and the image which turned off the light source 23. FIG. Then, an area with a large change in luminance value is detected as the finger area. As a result, the authentication processing unit 10 can stably detect the contour of the finger 1.

In addition, the authentication system of the sixth embodiment can stably acquire a clear finger vein pattern even when the finger 1 is placed on the finger holder 25 in a bent state. This is because even in such a case, the principle that infrared light from the light source 23 scatters inside the finger 1 and proceeds to the outside does not change.

However, when the finger 1 is placed on the finger holder 25 in a bent state, the authentication processing unit 10 calculates the distance between the finger and the device based on the detected contour of the finger 1. The authentication processing unit 10 then corrects the magnification using the distance between the finger and the device. Thereby, the authentication processing part 10 can reduce the influence of the bending of the finger 1, and can perform a matching process. That is, since the bending of the finger 1 is allowed to some extent, the convenience of a user can be improved.

In addition, the authentication system of the sixth embodiment can acquire the finger vein pattern even when the finger 1 does not contact the finger rest 25. This reason is the same as the reason why a clear finger vein pattern can be acquired when the finger 1 in the first embodiment is floating (FIGS. 5A and 5B).

That is, in the authentication system of the sixth embodiment, the user can authenticate the finger 1 without contacting the finger holder 25. This allows the user to mitigate psychological resistance to contact.

Moreover, 6th Embodiment is applicable also to 2nd-5th embodiment by widening the width | variety of the opening part 30. FIG.

(Seventh embodiment)

In the seventh embodiment of the present invention, an authentication system is mounted on an information portable terminal.

17A is an explanatory diagram of the information portable terminal 242 of the seventh embodiment of the present invention.

The information portable terminal 242 is equipped with an authentication system. In addition, the information portable terminal 242 may mount either of the authentication systems of the first to sixth embodiments.

In addition, the input device 2 of the authentication system is provided such that the finger rest 25 appears on the surface of the information portable terminal 242. In addition, the input device 2 may be provided on the side of the information portable terminal 242.

The configuration of the authentication system mounted on the information portable terminal 242 is the same as that of the authentication system (FIG. 1) of the first embodiment except for the input device 2. In addition, the process of the authentication system mounted in the information portable terminal 242 is the same as that of the authentication system (FIG. 7 etc.) of 1st Embodiment. The same configuration and processing will be omitted.

17B is a side view of the input device 2 mounted in the information portable terminal 242 of the seventh embodiment of the present invention.

The input device 2 is the same as the input device (FIGS. 3A, 3B, and 3C) of the first embodiment except that the light source window 43 is included. The same configuration is given the same number and the description is omitted.

The light source light window 43 is provided on the same plane as the surface of the information portable terminal 242. In addition, the light source light window 43 covers the upper part of the light source 23 and the upper part of the opening 30. The light source window 43 is a material transparent to infrared light.

In addition, the finger rest 25 may be a shape having a curved recess or may be a planar shape. In addition, when the finger rests 25 have a planar shape, the presentation position of the finger 1 may be printed on the surface, or the surface may be made of a material having a different touch. As a result, the user can grasp the presentation position of the finger 1 and the moving direction.

(8th Embodiment)

In an eighth embodiment of the present invention, an authentication system is mounted on an information portable terminal.

18A is an explanatory diagram of the information portable terminal 242 of the eighth embodiment of the present invention.

The information portable terminal 242 is equipped with an authentication system. In addition, the information portable terminal 242 may mount either of the authentication systems of the first to sixth embodiments.

In addition, the input device 2 of the authentication system is installed in the side of the information portable terminal 242 in a state where it can be taken out. This explanatory diagram shows the information portable terminal 242 with the input device 2 drawn out. Then, the input device 2 is moved to the left by physical or software control. Then, the input device 2 can be stored inside the information portable terminal 242.

Thereby, the information portable terminal 242 can mount the authentication system even when the input device 2 of the authentication system cannot be installed on the surface.

The configuration of the authentication system mounted on the information portable terminal 242 is the same as that of the authentication system (FIG. 1) of the first embodiment except for the input device 2. In addition, the process of the authentication system mounted in the information portable terminal 242 is the same as that of the authentication system (FIG. 7 etc.) of 1st Embodiment. The same configuration and processing will be omitted.

18B is a front view of the input device 2 mounted in the information portable terminal 242 of the eighth embodiment of the present invention.

The input device 2 is the input device of the first embodiment (Figs. 3A, 3B and Fig.) Except for the point including the reflecting portion 302, the position of the infrared transmission filter 27 and the position of the imaging device 29. Same as 3C). The same configuration is given the same number and the description is omitted.

The reflection unit 302 is provided inside the input device 2. The reflecting unit 302 is, for example, a prism or an optical fiber, and changes the course of the infrared light.

Moreover, the imaging device 29 is provided in the information portable terminal 242 toward the direction of the reflecting part 302. In addition, the infrared transmission filter 27 is provided between the imaging device 29 and the reflector 302.

The imaging device 29 captures the infrared light passing through the opening 30, the reflecting unit 302, and the infrared transmission filter from the outside of the input device 2. That is, the imaging device 29 picks up the infrared light whose path is changed by the reflector 302.

(Ninth embodiment)

In the ninth embodiment of the present invention, the authentication system is mounted on the door knob.

19A is an explanatory view of the knob 264 of the door 262 of the ninth embodiment of the present invention. 19B is a side view of the input device 2 mounted on the knob 264 of the door 262 of the ninth embodiment of the present invention.

The knob 264 of the door 262 is equipped with an authentication system. In addition, the knob 264 may mount any of the authentication systems of the first to sixth embodiments.

That is, the knob 264 is provided with an input device 2, an authentication processing unit 10, and a communication cable 268. The communication cable 268 connects the input device 2 and the authentication processing unit 10.

The configuration of the authentication system mounted on the knob 264 is the same as that of the authentication system (Fig. 1) of the first embodiment. In addition, the process of the authentication system mounted in the knob 264 is the same as that of the authentication system (FIG. 7 etc.) of 1st Embodiment. The same configuration and processing will be omitted.

The user holds the knob 264 when opening the door 262. At this time, the input device 2 mounted in the knob 264 acquires an image of the finger vein pattern, and transmits the acquired image to the authentication processing unit 10.

The authentication processing unit 10 performs an authentication process on the image received from the input device 2. The authentication processing unit 10 unlocks the door if the image matches the authentication data stored in the storage device 14.

Therefore, the user only needs to remove the knob 264.

Since the authentication system of this embodiment can authenticate by the natural operation of a user, the convenience of a user can be improved.

Similar to the knob 264 of the door 262, the authentication system of the present embodiment may be mounted on a mobile phone, a steering wheel of an automobile, a grip of a motorcycle, or the like. The authentication system is mounted on a part held by the user, so that authentication can be performed by the user's natural operation.

In addition, when the corresponding part is gripped by the user, since the authentication system completes the authentication, the next operation of the user can be assisted by using the authentication result.

For example, the authentication system assists the user in opening the door 262 when the authentication is completed. Specifically, the authentication system may tilt the knob 264 automatically, open the door 262 automatically, or control the door 262 to open with a light force.

This allows the authentication system not only to authenticate the user, but also to assist the user's operation.

(10th embodiment)

In a tenth embodiment of the present invention, the present invention is applied to a probe type authentication device.

20A is a probe type authentication device of a tenth embodiment of the present invention. 20B is a side view of the input device 2 applied to the probe type authentication device of the tenth embodiment of the present invention.

The probe type authentication device authenticates the probe 282 by touching a part of the body.

The probe 282 carries an authentication system. In addition, the probe 282 may mount either of the authentication systems of 1st-6th embodiment.

In addition, the structure of the authentication system mounted in the probe 282 is the same as that of the authentication system (FIG. 1) of 1st Embodiment. In addition, the process of the authentication system mounted in the probe 282 is the same as that of the authentication system (FIG. 7 etc.) of 1st Embodiment. The same configuration and processing will be omitted.

By touching the probe 282 to a portion of the body, the authentication system images the vein pattern of that portion. A part of the body may be anywhere in the body, including, for example, a finger (a palm side, a back side, a side, a fingertip, etc.), a palm, a back of the hand, a wrist, an arm, a foot, a face, an ear, or a cheek. .

In the probe type authentication device, a vein pattern at any site can be used for personal authentication. Therefore, the probe type authentication device can make the security more robust since the information itself about the body part registered in advance in the authentication system is also kept secret.

In addition, the probe type authentication device may check the vein pattern after determining the identity of the body part.

Specifically, the probe type authentication device stores body position information in correspondence with registered authentication data. And the probe type authentication apparatus specifies the part of the body which the imaging device 29 image | photographed at the time of authentication.

For example, the probe type authentication device may input a part of the body by the user from the input unit 16. In addition, a feature amount may be calculated from the image picked up by the imaging device 29, and a part of the body may be specified based on the calculated feature amount. In addition, you may specify a part of a body by using general image processing for the image around the said part image picked up by the imaging device 29. FIG.

The probe type authentication device checks the vein pattern only when the specific body part and the registered body position information match. That is, the probe type authentication device does not perform the collation process when the specific body part and the registered body position information are different.

Thereby, since the probe type authentication apparatus can prevent authentication failure by comparing vein patterns of different sites, the accuracy of authentication can be improved.

Moreover, combining any one of Examples 2-5 with the said Example 1 or 6 of this application is naturally the range which this application discloses. In addition, it is also possible to employ | adopt suitably combining the structure of Examples 1-6 in the range without a contradiction about each of Examples 7-10.

INDUSTRIAL APPLICABILITY The present invention can be used for a personal authentication device installed in a personal computer, a portable terminal, an ATM, a car, a room entrance management, or the like.

Claims (12)

An interface on which a living body to be imaged is placed, a light source that emits infrared light, an imaging unit which picks up a blood vessel image of the living body by light from the light source, and an image calculating unit which processes the blood vessel image picked up by the imaging unit As an intravenous authentication device comprising: The interface forms an opening opening in the imaging direction of the imaging unit, The light source irradiates the living body with infrared light from the imaging side of the living body, And a light shielding member that shields light from which the path of the infrared light emitted from the light source passes in the direction crossing the imaging direction so that the infrared light emitted from the light source does not face the imaging direction. The method of claim 1, Intravenous authentication device, characterized in that the living body is a finger. The method of claim 2, And a plurality of the light sources arranged in the width direction of the finger placed on the interface. The method of claim 2, And the interface includes a plurality of recesses extending in the longitudinal direction of the finger on the interface. The method of claim 2, The interface is a vein authentication device, characterized in that the center concave shape. The method of claim 1, The interface is movable on the living body, The imaging section captures a plurality of vein images of the living body at different positions, And said image calculating unit synthesizes a plurality of vein images picked up by said imaging unit. The method of claim 6, It includes a movement amount measuring unit for measuring the movement amount of the living body, And said image calculating unit synthesizes a plurality of vein images captured by said imaging unit with reference to the movement amount measured by said movement amount measuring unit. The method of claim 1, And a light amount adjusting unit for adjusting the light amount of the light source. The method of claim 8, The imaging section captures a vein image of the living body at different light amounts adjusted by the light amount adjusting section, And the image calculating unit synthesizes the image picked up by the image capturing unit. The method of claim 1, And said interface is integrally formed with said light shielding member. An interface on which a living body to be imaged is placed, a light source that emits infrared light, an imaging unit which picks up the vein image of the living body by the light from the light source, and an image calculating unit which processes the vein image picked up by the imaging unit As an intravenous authentication device comprising: The interface forms an opening opening in the imaging direction of the imaging unit, The light source is, Is provided on the side of the opening, By emitting light with the imaging direction as the optical axis, infrared light is irradiated onto the living body from the imaging side of the living body, And a light shielding member disposed between the opening portion and the light source and covering at least half of an upper portion of the opening side of the light source. A vein authentication apparatus including an imaging section for photographing a vein image, an image calculating section for processing a vein image picked up by the imaging section, an interface on which a photographed body is placed, and a light source for emitting infrared light, The interface forms an opening opening in the imaging direction of the imaging unit, The light source is provided on the side of the opening, Infrared light is irradiated to the living body from the imaging side of the living body by emitting light with the direction tilted from the imaging direction opposite to the opening portion as the optical axis, A vein authentication device, disposed between the opening and the light source, the light shielding member covering an upper portion of the opening side of the light source.

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