JP2017142700A - Living body imaging apparatus, living body imaging method, living body imaging program, and storage medium for storing living body imaging program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a living body imaging apparatus which is compact and can image the image data of two or more parts of a living body with light having two or more wavelengths.SOLUTION: The living body imaging apparatus includes a light source which irradiates the living body with light having a first wavelength and light having a second wavelength, a first mirror which reflects the light having the first wavelength from the first part of the living body, a second mirror which reflects the light having the second wavelength from the second part of the living body, and an imaging part which receives the light reflected by the first mirror and the light reflected by the second mirror and generates the image data. The first mirror, the second mirror, and the imaging part are located on substantially the same straight line. The first mirror transmits the light having the second wavelength.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a biological imaging apparatus that images a living body, a biological imaging method, a biological imaging program, and a storage medium that stores the biological imaging program.

  With the spread of biometric authentication, devices for acquiring biometric image data, such as fingerprint image data and vein image data, have been developed.

  Patent Documents 1 to 3 describe an apparatus that captures an image of a finger placed on a sensor or a placement table and acquires fingerprint image data. However, when imaging is performed in a state where a site where a vein is imaged is placed on some member, there is a problem that blood flow of the finger is suppressed and it is difficult to acquire clear vein image data. Therefore, it is preferable that at least a finger portion from which vein image data is obtained is imaged without contacting the device.

  Patent Document 4 describes an apparatus that has a finger support protrusion 12 and is configured such that a finger is separated from a reading surface by a certain distance. The apparatus described in Patent Document 4 includes an IR cut mirror 24 that separates the optical paths of visible light and near-infrared light in order to reduce a defect in vein images caused by reflected light on the fingerprint surface of the finger. However, when an image sensor is provided on each of two optical paths separated by an IR cut mirror, there is a problem that the apparatus becomes large.

JP 2007-179434 A JP 2005-168627 A JP 2008-109592 JP 2009-54095 A

  From Patent Documents 1 to 4 described above, it has been impossible to realize a body imaging apparatus that is small and can image image data of two or more parts of a living body with light of two or more wavelengths. SUMMARY OF THE INVENTION An object of the present invention is to provide a living body imaging apparatus that is small and can image image data of two or more parts of a living body with light of two or more wavelengths.

  The first apparatus of the present invention includes a light source that irradiates a living body with light of a first wavelength and light of a second wavelength, a first mirror that reflects the light of the first wavelength from the first part of the living body, Receiving the second mirror that reflects the second wavelength light from the second part of the living body, the light reflected by the first mirror, and the light reflected by the second mirror to generate image data The first mirror, the second mirror, and the imaging unit are located on substantially the same straight line, and the first mirror transmits the light of the second wavelength. .

  According to the present invention, image data of two or more parts of a living body can be captured with light of two or more wavelengths.

It is a block diagram which shows the structural example of 1st embodiment. It is a block diagram which shows the modification of 1st embodiment. It is a block diagram which shows the modification of 1st embodiment. It is a block diagram which shows the structural example of 2nd embodiment. It is a block diagram which shows the structural example of 3rd embodiment. It is a flowchart which shows operation | movement of 3rd embodiment. It is a block diagram which shows the structural example of 4th embodiment. It is a block diagram which shows the structural example of 5th embodiment. It is a block diagram which shows the example of a hardware configuration. It is a block diagram which shows the example of a hardware configuration. It is a block diagram which shows the example of a hardware configuration.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. However, the components described in the following embodiments are exemplifications, and are not intended to limit the technical scope of the present invention.
(First embodiment)
A configuration example of the first embodiment will be described. FIG. 1 is a diagram illustrating a configuration example of a biological imaging apparatus 100 according to the first embodiment. The biological imaging apparatus 100 includes a light source 1, a first mirror 3, a second mirror 4, and an imaging unit 5.

  The living body imaging apparatus 100 images the first part and the second part of the living body, and generates image data of the first part and image data of the second part. For example, the image data of the first part may be fingerprint image data, and the image data of the second part may be vein image data. These image data generated by the biometric imaging device 100 are collated with image data registered in advance by an external authentication device and used for personal authentication, for example.

  The light source 1 irradiates the finger FG with light of the first wavelength and light of the second wavelength. The light source 1 may be a light emitting member such as an LED (Light Emitting Diode), a light bulb, or a fluorescent lamp. The first wavelength and the second wavelength are different wavelengths. The first wavelength is preferably a wavelength of light suitable for imaging the first part of the living body. The second wavelength is preferably a wavelength of light suitable for imaging the second part of the living body.

  In particular, it is preferable that the first wavelength is a wavelength of light that can be imaged by making the first part stand out from the second part of the living body. Similarly, the second wavelength is preferably a wavelength that allows the second part to stand out from the first part of the living body and image it. For example, the first wavelength may be 360 nm to 900 nm. The second wavelength may be 650 nm to 900 nm.

  The light source 1 may irradiate only light of the first wavelength and light of the second wavelength, or may irradiate light of other wavelengths. For example, the light source 1 may irradiate the finger FG with white light mixed with light of all wavelengths. Alternatively, the light source 1 may irradiate the finger FG with near-infrared light together with white light or instead of white light.

  The first mirror 3 and the second mirror 4 may be anything as long as they reflect light, and may be made of, for example, glass, aluminum, silver, plastic, or the like. Moreover, the 1st mirror 3 and the 2nd mirror 4 may consist of a member which reflects a specific wavelength and permeate | transmits a specific wavelength. For example, the first mirror and the second mirror may be a hot mirror or a cold mirror. Moreover, it is preferable that the upper part of the reflective surface of the 1st mirror 3 and the 2nd mirror 4 inclines in the direction away from the imaging part 5 so that the imaging part 5 can condense the light which each reflected.

  The 1st mirror 3 reflects the light of the 1st wavelength from the 1st site | part of a biological body. The first wavelength light from the first part of the living body may be, for example, light obtained by reflecting the first wavelength light emitted from the light source 1 at the first part of the living body. Or the light of the 1st wavelength from the 1st site | part of a biological body may be the light radiated | emitted from the 1st site | part of a biological body after the light of the 1st wavelength irradiated from the light source 1 permeate | transmits the inside of a biological body.

  The first mirror 3 may not reflect light having a wavelength other than the first wavelength. That is, the first mirror 3 may transmit light having a wavelength other than the first wavelength. However, the first mirror 3 transmits light of at least the second wavelength. Therefore, as shown in FIG. 1, the light of the second wavelength reflected by the second mirror 4 can pass through the first mirror 3 and reach the imaging unit 5.

  The second mirror 4 reflects light of the second wavelength from the second part of the living body. The second wavelength light from the second part of the living body may be, for example, light obtained by reflecting the second wavelength light emitted from the light source 1 at the second part of the living body. Or the light of the 2nd wavelength from the 2nd site | part of a biological body may be the light radiated | emitted from the 2nd site | part of a biological body after the light of the 2nd wavelength irradiated from the light source 1 permeate | transmitted in the biological body. The second mirror 4 may not reflect light having a wavelength other than the second wavelength. That is, the second mirror 4 may transmit light having a wavelength other than the second wavelength.

  The imaging unit 5 receives the light reflected by the first mirror 3 and the light reflected by the second mirror 4. Then, the imaging unit 5 generates image data based on the received light. The imaging unit 5 may be, for example, a camera having a CCD (Charge Coupled Device) sensor, a CMOS (Complementary Meta Oxide Semiconductor) sensor, an image processor, and the like. The imaging unit 5 generates image data by converting received light into image data.

  Here, the first mirror 3, the second mirror 4, and the imaging unit 5 are located on a substantially straight line in the biological imaging apparatus 100. “On substantially the same line” means that the first mirror 3, the second mirror 4, and the imaging unit 5 are strictly in a straight line when the biological imaging apparatus 100 is viewed from a specific direction (for example, the finger FG side in FIG. 1). It doesn't need to be located in. “Substantially on the same line” means, for example, that the first mirror 3 is such that at least a part of the light of the second wavelength reflected by the second mirror 4 can pass through the first mirror 3 and reach the imaging unit 5. And the 2nd mirror 4 and the imaging part 5 should just be located.

  In the biological imaging apparatus 100 of the first embodiment, the first mirror 3, the second mirror 4, and the imaging unit 5 are located on substantially the same straight line. Thereby, since the space required for arrangement | positioning of the 1st mirror 3, the 2nd mirror 4, and the imaging part 5 does not spread in two or more directions, the biological imaging device 100 becomes small. Furthermore, the biological imaging apparatus 100 can obtain image data of the first part of the living body using light of the first wavelength and image data of the second part of the living body using light of the second wavelength. Therefore, the biological imaging apparatus 100 is small and can capture image data of two or more parts of the living body with light having two or more wavelengths.

  In the above embodiment, the first mirror 3 transmits light having the second wavelength. However, the second mirror 4 may transmit light having the first wavelength. In this case, the imaging unit 5 may be located on the side opposite to the first mirror 3 when viewed from the second mirror 4 (on the right side of the second mirror 4 in FIG. 1). Also in this case, it is preferable that the upper part of the reflecting surface of the first mirror 3 and the second mirror 4 is inclined in a direction away from the imaging unit 5 so that the imaging unit 5 can collect the light reflected by each.

  Moreover, the biological imaging apparatus 101 of the first embodiment may include a filter 6 and a filter 7 as illustrated in FIG. The filter 6 may be a member that transmits the first wavelength and reflects wavelengths other than the first wavelength. The filter 7 may be a member that transmits the second wavelength and reflects wavelengths other than the second wavelength. By providing the filter 6 and the filter 7, the light of the first wavelength out of the light from the finger FG enters the first mirror 3, and the light of the second wavelength enters the second mirror 4. That is, the imaging unit 5 images the first part only with the first wavelength light from the first part, and images the second part only with the second wavelength light from the second part. Therefore, the image data generated by the imaging unit 5 clearly captures the first part and the second part. The biological imaging apparatus 101 may have either the filter 6 or the filter 7. In the above embodiment, one light source irradiates the finger FG with light of the first wavelength and light of the second wavelength. However, the present invention is not limited to this. For example, the biological imaging apparatus 100 may have a light source that emits light of a first wavelength and a light source that emits light of a second wavelength.

  Furthermore, the biological imaging apparatus 101 may have three or more mirrors as shown in FIG. The biological imaging apparatus 101 in FIG. 3 includes a third mirror 8 and a fourth mirror 9. The four mirrors and the imaging unit 5 are located on substantially the same line. In this case, the light source 1 irradiates the finger FG with light of four wavelengths of the first wavelength, the second wavelength, the third wavelength, and the fourth wavelength.

  And the 3rd mirror 8 reflects the light of the 3rd wavelength from the 3rd site | part of a biological body. The fourth mirror 9 reflects the fourth wavelength from the fourth part of the living body. The first mirror 3 transmits light of the second wavelength, the third wavelength, and the fourth wavelength. The third mirror 8 transmits light of the second wavelength and light of the fourth wavelength. The second mirror 4 transmits the fourth wavelength light.

As described above, the designer of the biological imaging apparatus 101 can appropriately determine the number of wavelengths of light emitted from the light source 1, the number of biological parts to be imaged, and the number of mirrors. However, since the plurality of mirrors and the imaging unit 5 are positioned on substantially the same line, the mirror positioned near the imaging unit 5 is a mirror positioned further away so that the optical path to the imaging unit 5 is not hindered by each mirror. It is desirable to transmit the light reflected.
(Second embodiment)
A configuration example of the second embodiment will be described. FIG. 4 is a diagram illustrating a configuration example of the second embodiment. In the second embodiment, it is assumed that the image data generated by the imaging unit 5 is collated with image data registered in advance. The second embodiment is different from the first embodiment in that the biological imaging apparatus 103 includes a control unit 14. Since the other structure of 2nd embodiment is the same as that of 1st embodiment, description is abbreviate | omitted.

  The imaging unit 5 includes an image of the first part of the living body obtained by the light incident from the first mirror 3 and an image of the second part of the living body obtained by the light incident from the second mirror 4. Image data (one image file) is generated. Therefore, when the collation process using the image data of the first part of the living body and the collation process using the image data of the second part are performed by different algorithms, the image data generated by the imaging unit 5 remains as it is. If it is used, the accuracy of the collation process is reduced. This is because the image data of the second part becomes noise in the algorithm that collates the image data of the first part, and the image data of the first part becomes noise in the algorithm that collates the image data of the second part. .

  Therefore, when the collation process using the image data of the first part of the living body and the collation process using the image data of the second part are performed by different algorithms, the image data generated by the imaging unit 5 is It is preferable to divide into image data of the first part and image data of the second part. Therefore, the control unit 14 first acquires the image data generated by the imaging unit 5. Then, the control unit 14 divides the acquired image data into image data of the first part and image data of the second part.

  For example, it is assumed that the image data of the first part is fingerprint image data and the image data of the second part is vein image data. In this case, the control unit 14 specifies and extracts the fingerprint shape from the image data generated by the imaging unit 5. Similarly, the control unit 14 specifies and extracts a vein shape from the image data generated by the imaging unit 5. Thereby, the control part 14 can acquire fingerprint image data and vein image data separately.

  In the second embodiment, since the control unit 14 divides the image data into the image data of the first part and the image data of the second part, the noise of the image data in the matching process is reduced and the accuracy of the matching process is improved.

Note that the control unit 14 may exist not in the biological imaging apparatus 103 but in an external device connected to the biological imaging apparatus 103. For example, a computer connected to the biological imaging apparatus 103 by wireless or wired may have the control unit 14.
(Third embodiment)
(Configuration of the third embodiment)
Next, a configuration example of the third embodiment will be described. FIG. 5 is a diagram illustrating a configuration example of the third embodiment. The biological imaging apparatus 104 of the third embodiment is different from the first embodiment in that it includes a control unit 15. The control unit 15 controls the light source 1 so that the first wavelength light and the second wavelength light are irradiated at different times. In addition, the control unit 15 controls the imaging unit 5 so as to generate image data when the light source 1 emits light of the first wavelength and when the light source 2 emits light of the second wavelength. .

  For example, the first wavelength is a wavelength of light suitable for imaging the first part of the living body. The second wavelength is a wavelength of light suitable for imaging the second part of the living body. Therefore, the image data generated by the imaging unit 5 when the light source 1 is radiating light of the first wavelength is image data in which the first part of the living body is clearly captured. Moreover, the image data which the imaging part 5 produces | generates when the light source 1 is irradiating the light of a 2nd wavelength is image data in which the 2nd site | part of a biological body is reflected clearly. That is, the control unit 15 can switch whether the imaging unit 5 generates image data of the first part of the living body or image data of the second part of the living body by controlling the light source 1.

Therefore, the living body imaging apparatus 104 according to the third embodiment also performs the matching process using the image data of the first part of the living body and the matching process using the image data of the second part using different algorithms. However, it is not necessary to perform processing for extracting biometric image data suitable for collation. That is, in the third embodiment, the imaging unit 5 generates image data in which the first part of the living body is clearly imaged and image data in which the second part is clearly imaged. Can be obtained.
(Operation of the third embodiment)
Next, the operation of the third embodiment will be described. FIG. 6 shows a flowchart for explaining the operation of the biological imaging apparatus 104. The biological imaging apparatus 104 is connected to be communicable with, for example, a computer. When the user activates a driver downloaded in advance to the computer, the biological imaging apparatus 104 is activated by a signal from the computer.

  When the living body imaging device 104 is activated, the control unit 15 controls the light source 1 to irradiate the finger FG with light of the first wavelength (S1). For example, the control unit 15 controls the light source 1 when the user's finger FG approaches the biological imaging apparatus 104. The proximity of the finger FG may be detected by a sensor (not shown) (such as a pressure sensor, an infrared sensor, or a capacitance sensor) included in the living body imaging device 104. Alternatively, the proximity of the finger FG may be detected by the control unit 15 based on the brightness, feature amount, color, and the like of the image data generated by the imaging unit 5.

  Next, the control unit 15 controls the imaging unit 5 to generate image data (S2). The control unit 15 controls the imaging unit 5 in a state where the light source 1 irradiates the finger FG with light of the first wavelength. Therefore, the imaging unit 5 receives light reflected by the first mirror 3 out of light having the first wavelength from the finger FG, and generates image data.

  And the control part 15 controls the light source 1, and complete | finishes irradiation of the light of 1st wavelength. Thereafter or simultaneously with this, the control unit 15 controls the light source 1 to irradiate light of the second wavelength (S3). That is, the control unit 15 controls the light source 1 to switch between irradiation with light having the first wavelength and irradiation with light having the second wavelength. Thereafter, the control unit 15 controls the imaging unit 5 to generate image data again (S4). The control unit 15 controls the imaging unit 5 in a state where the light source 1 irradiates the finger FG with light of the second wavelength. Therefore, the imaging unit 5 receives the light reflected by the second mirror 4 among the light of the second wavelength from the finger FG, and generates image data. The control unit 15 may transmit the two image data generated by the imaging unit 5 to the computer.

  The living body imaging apparatus 104 of the present embodiment irradiates the second wavelength after irradiating the first wavelength light, but may irradiate the first wavelength light after irradiating the second wavelength light. Further, the control unit 15 may perform irradiation of the light source 1 in S1 when the user inputs an instruction to start imaging from the computer.

Note that the control unit 15 may exist not in the biological imaging apparatus 104 but in an external device connected to the biological imaging apparatus 104. For example, a computer connected to the biological imaging apparatus 104 by wireless or wired may have the control unit 15.
(Fourth embodiment)
Next, a configuration example of the fourth embodiment will be described. FIG. 7 is a diagram illustrating a configuration example of the biological imaging apparatus 105. The biological imaging apparatus 105 is different from the biological imaging apparatus 100 in that the biological imaging apparatus 105 includes a light source 11 that emits light of a first wavelength, a light source 10 that emits light of a second wavelength, a housing 16, and a mounting table 17.

  The housing 16 has another configuration inside, and separates the biological imaging apparatus 105 from the outside. Further, the components in the living body imaging device 105 are fixed to the housing 16. As a result, the influence of the external environment on the generation of image data is reduced, and the biological imaging apparatus 105 can be easily carried.

  The mounting table 17 is a table for mounting the tip of the finger FG. The mounting table 17 is preferably curved so as to follow the shape of the finger FG. Moreover, it is preferable that the mounting table 17 is a size which does not contact the site | part from the 1st joint of a finger to a root.

  The light source 11 emits light having a first wavelength. The light of the first wavelength is visible light, and may be, for example, white light mixed with light of all wavelengths classified as visible light. For example, the first wavelength may be 360 nm to 900 nm. Visible light does not easily pass through the living body and is easily reflected on the surface of the living body. Further, when visible light is irradiated onto the finger FG, the light hits the ridges in the fingerprint on the living body surface, but the light is blocked by the valley lines and not so much. For this reason, when the finger FG is irradiated with visible light, the contrast between the ridge and the valley becomes clear. That is, the imaging unit 5 can generate clear fingerprint image data by irradiating the finger FG with visible light.

  The light source 12 emits light having a first wavelength. The second wavelength is near-infrared light, and is preferably light having a wavelength of 650 nm to 900 nm, for example. The blood in the blood vessels of a living body contains a lot of hemoglobin. And hemoglobin absorbs near-infrared light, particularly light having a wavelength of 650 nm to 900 nm. Accordingly, when the near-infrared light is irradiated with the finger FG, the light is well absorbed in the blood vessel portion, so that the blood vessel portion looks dark from the outside of the finger FG. That is, when near-infrared light is irradiated to the finger FG, the imaging unit 5 can generate clear vein image data.

  In the present embodiment, the first part of the living body is a part where a fingerprint on the surface of the living body exists. In particular, the part from the tip of the finger to the vicinity of the first joint is preferable as the first part because there are many characteristic fingerprint patterns. Therefore, the light source 11 is preferably provided in the vicinity of the first joint from the tip of the finger FG. In particular, it is preferable that the light source 11 is disposed near the tip side of the finger FG or near the side surface of the finger FG so that the image of the light source 11 itself does not appear in the image.

  In the present embodiment, the second part of the living body is a part where blood vessels inside the living body exist. The part from the first joint of the finger to the base is preferable as the second part because it is easy to obtain a clear vein pattern. Therefore, the light source 10 is preferably provided in the vicinity of the site from the first joint of the finger to the base. In particular, a light source is provided on the back side of the finger FG (upper side of the finger FG in FIG. 4) or the side surface (front side of the finger FG in FIG. 4) so that the light reflected on the surface of the finger FG does not appear in the image. 10 is preferably provided. Thereby, it is possible to prevent the blood vessel image captured by the light transmitted through the finger FG from becoming unclear due to the light reflected from the surface of the finger FG.

  Note that when the vein is compressed, blood flow is suppressed, and the vein pattern may not be clearly imaged. Therefore, it is preferable that the image data is generated by the imaging unit 5 in a state where at least the second part of the living body does not contact any member of the biological imaging apparatus 105.

  The first mirror 3 reflects visible light reflected by the first part of the living body. For example, as shown in FIG. 4, the first mirror 3 reflects visible light reflected on the surface from the tip of the finger FG to the vicinity of the first joint toward the imaging unit 5. The second mirror 4 reflects the near-infrared light that is transmitted through the inside of the living body and emitted from the second portion of the living body. For example, as shown in FIG. 4, the second mirror 4 reflects near-infrared light that is transmitted through the inside of the finger FG and radiated from a portion from the first joint to the root to the imaging unit 5.

  In addition, the 1st mirror 3 permeate | transmits the light of a 2nd wavelength similarly to 1st embodiment. For example, the first mirror 3 reflects visible light and transmits near-infrared light. That is, the first mirror 3 may be a cold mirror. Therefore, the near infrared light reflected by the second mirror 4 can reach the imaging unit 5 without being blocked by the first mirror 3. The second mirror 4 may reflect near infrared light and transmit visible light. That is, the second mirror 4 may be a hot mirror.

  The imaging unit 5 generates fingerprint image data from visible light received from the first mirror 3 with the above configuration. Further, the imaging unit 5 generates vein image data from the near infrared light received from the second mirror 4.

  Note that, as in the third embodiment, when the biological imaging apparatus 105 irradiates light of the first wavelength and light of the second wavelength at different times, the imaging unit 5 separately prints the fingerprint image data and the vein image data. Can be obtained. That is, if the irradiation of visible light from the light source 2 and the irradiation of near-infrared light from the light source 10 are performed at different times, the imaging unit 5 can generate fingerprint image data and vein image data separately. When visible light irradiation by the light source 2 and near-infrared light irradiation by the light source 10 are performed at the same time, it is preferable to perform processing for extracting a fingerprint region or a vein region from the image data generated by the imaging unit 5. . Thereby, the noise of the image is reduced, and the accuracy of the fingerprint matching process or the vein matching process is improved.

  With the above configuration, the biological imaging apparatus 105 of the fourth embodiment can obtain clear fingerprint image data and clear vein image data.

The light emitted by the light source 10 is not limited to near infrared light. The light source 10 may emit, for example, mid-infrared light or far-infrared light.
(Fifth embodiment)
A configuration example of the fifth embodiment will be described. FIG. 8 is a diagram illustrating a configuration example of the biological imaging apparatus 106 according to the fifth embodiment. The biological imaging apparatus 106 is different from the first embodiment in that it includes a prism body 12 instead of the first mirror 3. The prism body 12 may be a polyhedron made of glass, plastic, crystal, or the like, for example. As shown in FIG. 8, the prism body 12 has a reflection surface 13 that reflects light having the first wavelength toward the imaging unit 5. The reflecting surface 13 plays the role of the first mirror 3 in the first embodiment 1.

  The prism body 13 is designed so that the optical path length of the first wavelength light received by the imaging unit 5 is substantially the same as the optical path length of the second wavelength light received by the imaging unit 5. That is, the prism body 13 has an optical path length until the first wavelength light from the first part of the living body reaches the imaging unit 5 and until the second wavelength light from the second part of the living body reaches the imaging unit 5. The light of the first wavelength is reflected inside the prism body 13 so that the optical path length of the prism body 13 is substantially the same.

  In FIG. 8, the light having the first wavelength from the first part of the finger FG is shown to be totally reflected by the reflecting surface 13 after being totally reflected twice in the prism body 12. I can't. The optical path of the first wavelength light from the first part of the living body and the shape of the prism body 13 can be appropriately changed by the designer. However, as described above, it is preferable that the optical path length of the first wavelength light and the optical path length of the second wavelength light shown in FIG. 8 are substantially the same.

Normally, when two or more subjects with different distances from the imaging unit are imaged, only one of the subjects is in focus, and the other subject is unclear (the image is blurred). However, with the above-described configuration, the optical path length of light from the first part of the living body and the optical path length of light from the second part of the living body are substantially the same. Therefore, the imaging unit 5 can focus on both the first part and the second part, and can generate image data that clearly shows each part.
(Hardware configuration)
Next, a hardware configuration example of the present invention will be described. FIG. 9 is a diagram illustrating a configuration example of a biological imaging system 1000 that includes at least one of the biological imaging apparatuses 100 to 102.

  The biometric imaging device 107 in FIG. 9 may be at least one of the biometric imaging devices 100 to 102 described above. The biological imaging apparatus 107 may be connected to the computer 21 via a USB (Universal Serial Bus) port. Alternatively, the biological imaging apparatus 107 may be connected to the computer 21 via other wired or wireless communication. The biological imaging apparatus 107 may perform turning on and off of the light source, generation of image data by the imaging unit, transmission of image data, and the like under the control of the computer 21.

  The computer 21 may be any general computer. For example, the computer 21 may be a notebook PC, desktop PC, server, workstation, blade server, or the like. The computer 21 may be communicably connected to a server or another computer.

  9, the computer 21 includes a processor 1402, a memory 1404, a storage 1406, a north bridge 1408 connected to the memory 1404, and an expansion slot 1410. The computer 21 further includes a south bridge 1412 connected to the communication interface 1414 and the storage 1406. These components are connected to each other by a bus and fixed to the motherboard.

  The processor 1402 reads and executes instructions stored in the memory 1404, the storage 1406, and the like. The processor 1402 may execute an instruction to display an image on a display device (not shown).

  The processor 1402 may implement the control unit 14 and the control unit 15. That is, the processor 1402 may control the operation of the biological imaging apparatus 107. For example, the processor 1402 may control the biological imaging device 107 by transmitting and receiving signals via a USB port or the like. For example, the processor 1402 may turn on the light source in the biological imaging apparatus 107 and cause the imaging unit in the biological imaging apparatus 107 to generate image data. At this time, the processor 1402 realizes control of the biological imaging apparatus 107 by reading a program stored in the memory 1404 or the storage 1406. For example, the processor 1402 controls the biological imaging apparatus 107 by reading a program stored in advance in the storage 1406 as a device driver. The processor 1402 may be a circuit such as a CPU (Central Processing Unit) or ASICs (Application Specific Integrated Circuits).

  The memory 1404 is a computer-readable storage medium that stores information. The memory 1404 may be a volatile storage medium such as a RAM or a non-volatile storage medium such as a ROM. The memory 1404 may be an optical disk, a magnetic disk, or the like. The storage 1406 may be a large capacity computer readable storage medium. The storage 1406 may be, for example, a floppy (registered trademark) disk, a hard disk drive, an optical disk, a flash memory, or the like. The above-described embodiments are realized by executing instructions included in a computer program stored in a computer-readable storage medium.

  The north bridge 1408 connects, for example, a computer brain such as a CPU and a memory, and controls the timing and speed of data transfer. The north bridge 1408 mainly bridges data with devices operating at high speed. On the other hand, the south bridge 1412 bridges data with a relatively low-speed device. For example, the north bridge 1408 may be connected to the memory 1404, the display device 14, and an expansion slot 1410 that can accept an expansion card (not shown). The south bridge 1412 may be connected to the storage 1406 and the communication interface 1414.

  The communication interface 1414 may include various communication ports such as USB, Bluetooth (registered trademark), Ethernet (registered trademark), and wireless Ethernet. Further, these communication ports may be connected to one or a plurality of input / output devices, for example, a communication device such as a keyboard, a pointing device, a scanner, and a router. The biological imaging apparatus 107 may be connected to the computer 21 via the communication interface 1414.

  FIG. 10 is a diagram illustrating a configuration example of a biological imaging system 1001 that includes the biological imaging apparatus 107. In FIG. 10, unlike in FIG. 9, the biological imaging device 107 is connected to the mobile terminal 22.

  The mobile terminal 22 may be a mobile terminal such as a mobile phone, a smartphone, or a PDA (Personal Digital Assistant).

  The biological imaging apparatus 107 may be connected to the portable terminal 22 via the external interface 1462. Alternatively, the biological imaging apparatus 107 may be connected to the computer 21 via the communication interface 1466. Under the control of the portable terminal 22, the biological imaging apparatus 107 performs turning on and off of the light source, generation of image data by the imaging unit, transmission of image data, and the like.

  The mobile terminal 22 may include a display 1454, a transceiver 1468, an audio codec 1460, a control interface 1458, and a display interface 1456. The mobile terminal 22 may further include a communication interface 1466, a processor 1452, a GPS (Global Positioning System) reception module 1470, an additional memory 1474, a memory 1464, and an external interface 1462.

  The display 1454 may be, for example, a TFT LCD (Thin-Film-Transistor Liquid Crystal Display), an OLED (Organic Light Emitting Diode) display, and other displays. The display may be connected to the control interface 1458 or the display interface 1456. The processor 1452 may exchange information with the user of the mobile terminal 22 via the control interface 1458 and the display interface 1456.

  The display interface 1456 may be configured by a circuit. Display interface 1456 controls the display to display video and other information to the user. The control interface 1458 receives commands from the user. The control interface 1458 may then convert the received command for delivery to the processor 1452.

  Further, the mobile terminal 22 may have an external interface 1462 that enables communication with the processor 1402. The external interface 1462 enables communication between the peripheral device of the biometric data support apparatus 22 and the biometric data support apparatus 22. The external interface 1462 may provide wired communication or wireless communication.

  The expansion memory 1474 may be connected to the mobile terminal 22 via the expansion interface 1472. Further, the expansion memory 1474 may include, for example, a SIMM (Single In Line Memory Module) card interface. Further, the expansion memory 1474 may provide an additional storage area for the mobile terminal 22 and store applications and other information. Further, the additional memory 1474 may store information related to security. That is, the additional memory 1474 may function as a security management device for the mobile terminal 22. For example, the extension memory 1474 may be programmed with instructions for realizing the safe use of the mobile terminal 22.

  The mobile terminal 22 performs wireless communication via the communication interface 1466. The communication interface 1466 may include a digital signal processing circuit. The communication interface 1466 may implement communication under a mode or protocol such as GMS (Global System for Mobile Communication), SMS (Short Message Service), or EMS (Enhanced Messaging Service). Alternatively, the communication interface 1466 may implement communication under a mode or protocol such as MMS (Multimedia Messaging Service), CDMA (Code Division Multiple Access), or TDMA (time division multiple access).

  Furthermore, the communication interface 1466 is a mode or protocol that implements a communication mode such as PDC (Personal Digital Cellular), WCDMA (registered trademark) (Wideband Code Division Multiple Access), CDMA2000, GPRS (General Packet Radio Service) in communication mode. good. The communication described above occurs via the transceiver 1468, for example. In addition, communication using a narrow area, for example, communication using Bluetooth, Wi-Fi (registered trademark), or the like may be generated via the transceiver 1468.

  The GPS receiving module 1470 may provide data used by an application that operates on the mobile terminal 22. The data may be data related to position and navigation, for example.

  Further, the mobile terminal 22 may perform voice communication via the audio codec 1460. The audio codec 1460 obtains audio information from the user and converts it to be usable as digital information. Furthermore, the audio codec 1460 generates voice that can be heard by the user. The information handled by the audio codec 1460 may be a voice call, a recorded sound (voice message, music file, etc.), a sound generated by an application on the mobile terminal 22, and the like.

  Since the processor 1452 and the memory 1464 are the same as those of the computer 21, description thereof is omitted.

  FIG. 11 is a diagram illustrating a hardware configuration of the biological imaging apparatus 108. The biological imaging device 108 may be any of the biological imaging devices 100 to 107 described above. The biological imaging apparatus 108 includes a light source 1, a mirror 3, a mirror 4, and an imaging unit 5 in addition to the configuration of the computer 21. The biological imaging apparatus 108 may not include the storage 1406.

  The light source 1 may be a light emitting member such as an LED, a light bulb, or a fluorescent lamp. The mirror 3 and the mirror 4 may be members that reflect light. In particular, the mirror 3 may be made of a member that reflects a specific wavelength and transmits a specific wavelength. The mirror 3 and the mirror 4 may be, for example, a hot mirror or a cold mirror. The imaging unit 5 may be a camera having, for example, a CCD sensor, a CMOS sensor, an image processor, and the like. The imaging unit 5 generates image data by converting received light into image data.

  The biological imaging apparatus 108 may be communicably connected to a computer such as a PC, a server, or a portable terminal via the communication interface 1414. The connection may be wireless or wired.

  The processor 1402 may implement the control unit 14 and the control unit 15. That is, the processor 1402 may control the light source 1 and the imaging unit 5. At this time, the processor 1402 may realize the functions of the control unit 14 and the control unit 15 by reading a program stored in the memory 1404 or the storage 1406. Alternatively, the processor 1402 may realize the functions of the control unit 14 and the control unit 15 by receiving a signal from an external computer.

  Since other configurations in the biological imaging apparatus 108 are the same as those of the computer 21, the description thereof is omitted.

  Each embodiment mentioned above is only an example which materialized the present invention, and can be variously changed if it is in the range of the meaning of the present invention indicated in the claim.

DESCRIPTION OF SYMBOLS 1 Light source 3 1st mirror 4 2nd mirror 5 Image pick-up part 6 Filter 7 Filter 8 Third mirror 9 Fourth mirror 10 Light source 11 Light source 12 Prism body 13 Reflecting surface 14 Control part 15 Control part 16 Case 17 Mounting stand 21 Computer 22 Portable terminal 100 biological imaging apparatus 101 biological imaging apparatus 102 biological imaging apparatus 103 biological imaging apparatus 104 biological imaging apparatus 105 biological imaging apparatus 106 biological imaging apparatus 107 biological imaging apparatus 108 biological imaging apparatus 1402 processor 1404 memory 1406 storage 1408 north bridge 1410 expansion slot 1412 South Bridge 1414 Communication Interface 1452 Processor 1454 Display 1456 Display Interface 1458 Control Interface 1460 O Iokodekku 1466 communication interface 1468 transceiver 1462 external interface 1464 memory 1470 GPS receiver module 1472 Expansion interface 1474 Additional Memory FG finger

Claims (6)

A light source that irradiates the living body with light of the first wavelength and light of the second wavelength;
A first mirror that reflects light of the first wavelength from the first part of the living body;
A second mirror that reflects light of the second wavelength from the second part of the living body;
An imaging unit that receives the light reflected by the first mirror and the light reflected by the second mirror and generates image data;
The first mirror, the second mirror, and the imaging unit are located on substantially the same straight line,
The first mirror is a biological imaging apparatus that transmits light of the second wavelength. The living body imaging apparatus according to claim 1, wherein the light source irradiates light of the first wavelength and light of the second wavelength at different times. The first mirror is one surface of a prism body,
The prism body includes an optical path length until the first wavelength light from the first part of the living body reaches the imaging unit, and the second wavelength light from the second part of the living body to the imaging unit. The living body imaging apparatus according to claim 1, wherein the first wavelength light from the first portion of the living body is reflected inside the prism body so that an optical path length to reach is substantially the same. The light of the first wavelength is visible light,
The light of the second wavelength is near infrared light,
The first mirror reflects the light of the first wavelength reflected by the first part of the living body,
The second mirror transmits the inside of the living body, reflects the light of the second wavelength emitted from the second part of the living body,
The living body according to any one of claims 1 to 3, wherein the imaging unit generates fingerprint image data from the received light of the first wavelength and generates vein image data from the received light of the second wavelength. Imaging device. Irradiate the living body with light of the first wavelength and light of the second wavelength,
Reflecting the first wavelength light from the first part of the living body by a first mirror;
The second wavelength light from the second part of the living body is reflected by a second mirror;
Receiving the light reflected by the first mirror and the light reflected by the second mirror, and generating image data;
The reflection by the first mirror, the reflection by the second mirror, and the light reception are performed on substantially the same straight line,
The first mirror is a biological imaging method that transmits light of the second wavelength. On the computer,
Treatment of irradiating the living body with light of the first wavelength and light of the second wavelength;
A process of reflecting light of the first wavelength from the first part of the living body by a first mirror;
A process of reflecting light of the second wavelength from the second part of the living body by a second mirror;
Receiving the light reflected by the first mirror and the light reflected by the second mirror and generating image data; and
The reflection by the first mirror, the reflection by the second mirror, and the light reception are performed on substantially the same straight line,
The first mirror is a biological imaging program that transmits light of the second wavelength.

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