JP2000259821A - Fingerprint input device and individual identification system using the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a fingerprint input device with excellent handleability capable of simultaneously inputting the fingerprint of an individual and predetermined intrinsic data for each individual. SOLUTION: This fingerprint input device is provided with a multi-stage prism 11, an illumination device 21, an image receiver 23 and a shadow mask 12. The multi-stage prism 11 is provided with a detection plane (11a) formed of a transparent body where a finger tip F is tightly adhered and a slope (11b) disposed by being inclined for a prescribed angle to the detection plane (11a) for passing through reflected light from the detection plane (11a). The illumination device 21 irradiates reference light reflected on the detection plane (11a) inside the multi-stage prism 11. The image receiver 23 reads an image formed by the reflected light from the detection plane (11a) made to pass through the slope 11b of the multi-stage prism 11. The shadow mask 12 is interposed between the slope of the multi-stage prism 11 and the image receiver 23 and interrupts a part of the reflected light from the detection plane (11a) by a predetermined intrinsic pattern.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[0001] 1. Field of the Invention [0002] The present invention relates to a fingerprint input device for inputting a fingerprint of an individual, and an individual identification system using the device.

[0002]

2. Description of the Related Art Conventionally, as a fingerprint input device of this type, as shown in, for example, US Pat. No. 5,796,858, a detection surface formed of a transparent body and having a fingertip in close contact therewith is known. A prism disposed at a predetermined angle to the detection surface and having an inclined surface through which light reflected from the detection surface passes, irradiation means for irradiating the prism with reference light reflected on the detection surface, Image receiving means for reading an image formed by the reflected light from the detection surface that has passed through the inclined surface, and irradiating the reference light into the prism by the irradiation means in a state in which the fingertip is in close contact with the detection surface, and from the same detection surface In some cases, the image of the fingerprint of the fingertip appearing in the reflected light is read by the image receiving means.

The above fingerprint input device has been used in, for example, a personal identification system. In this case, the personal identification system stores in advance data representing a fingerprint as personal information, and compares the stored data representing the fingerprint with data representing the image read by the image receiving means. I was trying to identify individuals. In particular, the data representing the fingerprint is stored in association with predetermined data unique to each individual such as an ID number.
When the data representing the image is input by the fingerprint input device, the unique data is also input separately,
The data representing the image may be compared with only the data corresponding to the separately input unique data among the stored data to reduce the time required for the matching. there were.

[0004]

However, in the above-mentioned conventional fingerprint input device, the image read by the image receiving means represents only the fingerprint of the fingertip closely attached to the detection surface.
Therefore, for example, as in a personal identification system that specifies fingerprint data to be collated with the unique data in advance,
If the device is applied to a system for inputting unique data for each individual other than an image representing an individual's fingerprint, there is a problem that it becomes necessary to input the unique data separately and the usability is deteriorated. .

[0005]

SUMMARY OF THE INVENTION The present invention has been made to address the above-described problems, and has as its object to provide an easy-to-use fingerprint that allows simultaneous input of an individual's fingerprint and predetermined individual data for each individual. It is an object of the present invention to provide an input device and an easy-to-use personal identification system in which a collation time using the device is short.

In order to achieve the above object, the first aspect of the present invention is described.
In the fingerprint input device including the prism, the irradiating unit, and the image receiving unit, the configuration is characterized in that the reflection from the detection surface that is interposed between the inclined surface of the prism and the image receiving unit and passes through the inclined surface of the prism. That is, a blocking means for blocking a part of light with a predetermined unique pattern is provided. According to this, a part of the reflected light from the detection surface of the prism reaches the image receiving unit after being blocked by the blocking unit in a specific pattern determined in advance. Therefore, since the fingerprint read by the fingertip closely attached to the detection surface and the unique pattern appear together in the image read by the image receiving means, the fingerprint of the individual and the unique data of each individual are input simultaneously. This improves the usability of the fingerprint input device.

A second structural feature of the present invention is that in the fingerprint input device having the first feature, the prism is constituted by a multistage prism having a plurality of inclined surfaces. According to this, since the prism can be formed in a plate shape, the configuration of the fingerprint input device can be reduced in size.

According to a third structural feature of the present invention, in the fingerprint input device having the first or second structural feature, the blocking means may be connected to the detection surface passing through the inclined surface of the prism. Is constituted by a plate-shaped member provided with a plurality of optical paths for passing the reflected light to the image receiving means side. According to this, since the blocking means has a three-dimensional configuration and it is difficult to accurately reproduce the optical path, unauthorized copying of the blocking means becomes difficult, and the security of the fingerprint input device is improved.

A fourth structural feature of the present invention is a fingerprint input device having the third structural feature.
A plurality of optical paths of the plate-shaped member are formed so as to be inclined with respect to a thickness direction of the plate-shaped member. According to this, by adjusting the thickness of the plate-like member and the angle of inclination of the optical path, it is possible to limit the light reaching the image receiving means to only the reflected light from the detection surface of the prism. The reading accuracy of the image receiving means can be ensured after setting the optical path to the means short. Therefore, the configuration of the fingerprint input device can be reduced in size.

According to a fifth structural feature of the present invention, in the fingerprint input device having any one of the first to fourth structural features, the prism and the blocking means are integrally formed. It is formed in a card shape. A sixth structural feature of the present invention is the fingerprint input device having the first to fourth structural features, wherein the prism, the image receiving unit, the irradiating unit, and the blocking unit are provided in the same casing. It was contained. According to these, since it becomes possible to carry the blocking means corresponding to the pattern unique to each individual for each individual, the usability of the fingerprint input device is improved.

According to a seventh aspect of the present invention, there is provided a personal identification system using a fingerprint input device having any one of the first to sixth aspects, as personal information. Storage means for storing data representing the fingerprint of the fingerprint input device in association with the pattern to be cut off by the blocking means of the fingerprint input device, and an image read by the image receiving means of the fingerprint input device from the data stored in the storage means. A reading means for reading data corresponding to the pattern included and blocked by the blocking means, and a matching means for matching data read by the reading means with data representing an image read by the image receiving means are provided. It is in. According to this, the reading unit reads out data corresponding to the pattern included in the image read by the image receiving unit of the fingerprint input device and blocked by the blocking unit from the data stored in the storage unit, Collating means collates the data read by the reading means with the data representing the image read by the image receiving means. Therefore, the data to be collated by the collating means out of the data stored in the storage means is specified in advance based on the pattern blocked by the blocking means, so that the time required for the collation is reduced. Further, also in this case, since the fingerprint of the individual and the pattern are input simultaneously in the fingerprint input device, the usability of the personal identification system is kept high.

An eighth structural feature of the present invention is that a plate-shaped fingerprint input card mounted on a fingerprint detector provided with an irradiating means and an image receiving means is formed of a transparent body, and is provided with a fingerprint inputting means. With the card attached to the fingerprint detector, the fingertip is brought into close contact with the front side, and the detection surface that reflects the reference light emitted by the irradiation means on the back side, and is arranged at a predetermined angle to the detection surface A prism having an inclined surface through which the reflected light from the detecting surface passes, and a part of the reflected light from the detecting surface reaching the image receiving means passing through the inclined surface of the prism is blocked by a predetermined unique pattern. And a shut-off means. Also in this case, similarly to the case of the fingerprint input device having the feature of the first configuration, in the image read by the image receiving means, both the fingerprint of the fingertip closely attached to the detection surface and the unique pattern appear. Therefore, the fingerprint of the individual and the data unique to the individual are input at the same time. Further, similarly to the case of the fingerprint input device having the fifth structural feature, it is possible to carry a blocking unit corresponding to the unique pattern for each individual.

[0013]

DETAILED DESCRIPTION OF THE INVENTION a. First Embodiment Hereinafter, a first embodiment of the present invention will be described with reference to the drawings. FIG. 1 schematically shows a fingerprint input device according to the embodiment. This fingerprint input device includes a plate-like (thickness of about 50 μm to 2 mm) fingerprint input card 10 carried by each individual, and a fingerprint detector 20 to which the card 10 is attached.
It is composed of

The fingerprint input card 10 includes a multi-stage prism 11 formed of a transparent body in a plate shape, and a plate-shaped shadow mask 12 disposed below the prism 11 as blocking means. As shown in detail in FIG. 2, the multi-stage prism 11 has a detection surface 1 on which the fingertip F is in close contact with the upper side.
1a and a plurality of inclined surfaces 1 on the lower side.
1b. Each inclined surface 11b has a detection surface 11a.
Are arranged side by side at a predetermined angle in the same direction so as to allow the reflected light from the detection surface 11a to pass therethrough.

The shadow mask 12 has a plurality of through holes 12.
a. Each through hole 12a is an optical path formed in a linear shape parallel to each inclined surface 11b of the multi-stage prism 11, and passes through the shadow mask 12 in a direction perpendicular to the inclined surface 11b and passes through the inclined surface 11b. The reflected light from the detection surface 11a is passed downward. The shadow mask 12 transmits the reflected light from the detection surface 11a to each through-hole 1.
The light is passed through only 2a to block the remaining portion of the reflected light. In this case, the shadow mask 12 has a through hole 12a.
The above arrangement allows the reflected light to be blocked by a unique pattern representing an ID number predetermined for each fingerprint input card 10. Each of the through holes 12a penetrates the shadow mask 12 in a direction inclined with respect to the thickness direction thereof.
The upper end and the lower end are set to a thickness that does not overlap in the same thickness direction, so that light passing through the through hole 12a is limited to only reflected light from the detection surface 11a of the multi-stage prism 11. I have.

Here, a method of manufacturing the multi-stage prism 11 and the shadow mask 12 will be described. When manufacturing the multi-stage prism 11, first, a mold is manufactured using a silicon wafer. In this case, first, the surface of the silicon wafer having the orientation flat in the (100) direction is formed to be inclined with respect to the (110) direction, and a slit-shaped mask pattern perpendicular to the orientation flat is formed on the surface. This mask pattern may be formed using, for example, a photoresist, a metal mask made of silicon nitride or sputtered copper that has been patterned in advance, or the like. Then, the silicon wafer having the mask pattern formed thereon is placed in an aqueous solution in which silicon such as potassium hydroxide or tetramethylammonium hydroxide is dissolved at a different rate for each crystal orientation, so that the silicon wafers are placed on the surface of the silicon wafer. A plurality of parallel grooves are formed to create a mold for the multi-stage prism 11. A liquid transparent material (eg, acryl, glass, or the like) is poured into the mold, cooled and solidified to form a multi-stage prism 1.
1 is generated.

When the shadow mask 12 is manufactured, first, the surface of a silicon wafer having an orientation flat (112) is formed to be inclined with respect to the (110) direction. After forming a slit-shaped mask pattern perpendicular to the orientation flat on the surface, this silicon wafer is placed in an aqueous solution such as potassium hydroxide or tetramethylammonium hydroxide on the surface of the silicon wafer. Is formed. By cutting out this silicon wafer with a dicer or the like, the shadow mask 12 is manufactured. Note that the multi-stage prism 11 and the shadow mask 12 may be formed by other fine processing techniques such as electric discharge machining, dry etching, and wet etching. Alternatively, the mold may be formed by, for example, molding using a mold formed by the fine processing technique.

The fingerprint input card 10 also has a switch 13 (see FIG. 3). The switch 13 detects the contact of the fingertip F with the detection surface 11a of the multi-stage prism 11 based on a change in capacitance. The switch 13 may be a switch that photoelectrically detects the contact of the fingertip F, or a switch that detects the contact of the fingertip F.
The switch may be replaced by a push-button switch that is pressed by the same fingertip F when the sensor is brought into close contact with the detection surface 11a, or a switch that detects the contact based on the light amount of, for example, a photocoupler.

The fingerprint detector 20 includes an illuminating device 21 as an irradiating device, a lens 22, and an image receiving device 23 as an image receiving device. The illumination device 21 is configured by, for example, a light emitting diode, and irradiates the reference light into the multi-stage prism 11 in response to detection of contact of the fingertip F by the switch 13 in a state where the fingerprint input card 10 is mounted on the fingerprint detector 20. I do. The lens 22 is provided on the inclined surface 1 of the multi-stage prism 11.
1b and the reflected light from the detection surface 11a that has passed through the shadow mask 12 is imaged on the image receiving device 23. The image receiving device 23 is constituted by a device capable of collecting two-dimensional light / dark information, such as a charge-coupled device or a complementary MOS, and reads an image formed by the lens 22.

The fingerprint detector 20 also includes a CPU 24 and an output unit 25. The CPU 24 converts the image read by the image receiving device 23 into data. In this case, the data to be converted may be image data representing the image itself, or may represent only the correlation between the characteristic points (for example, end points and branch points) of the fingerprint included in the image. You may. Further, the CPU 24 obtains information indicating the position of the fingertip F on the detection surface 11a of the multi-stage prism 11 from the image. In this case, the acquired position information may be, for example, the position and angle of the first joint portion or the outer edge portion of the fingertip F included in the image. Output unit 2
Reference numeral 5 is connected to the server computer 30 constituting the personal identification system together with the fingerprint input device, and outputs each data representing the image and the position information to the computer 30.

As shown in FIG. 3, the server computer 30 includes a received image storage unit 31, a relative position calculation unit 32, an ID
Extraction unit 33, reference data storage unit 34, image generation unit 3
5, a collating unit 36 and a determining unit 37. The received image storage unit 31 temporarily stores data representing an image output from the output unit 25 of the fingerprint detector 20. The relative position calculation unit 32 outputs the output unit 2 of the fingerprint detector 20.
Based on the position information output from 5, the relative positional relationship between the part representing the fingerprint of the fingertip F and the part blocked by the shadow mask 12 in the image stored in the received image storage unit 31 is calculated. . The ID extraction unit 33 extracts the ID number given to the used fingerprint input card 10 by recognizing the pattern of the part blocked by the shadow mask 12 from the image stored in the received image storage unit 31. Is what you do. The reference data storage unit 34 stores data representing a fingerprint as a plurality of personal information,
The IDs are stored in association with ID numbers predetermined for each individual.

The image generating unit 35 stores the received image storage unit 3
1 to generate data for collating with the image stored in the storage unit 1. This data is generated by reading out data corresponding to the ID number extracted by the ID extraction unit 33 from the data stored in the reference data storage unit 34, and converting the data into a fingerprint image represented by the data. ID extraction unit 3
3 generates data representing an image in which parallel lines of the pattern recognized by 3 are superimposed at the relative position calculated by the relative position calculator 32. The collation unit 36 is configured to receive the received image
1 and the image generated by the image generation unit 35 are compared. The determination unit 37 determines whether or not to authenticate the individual using the fingerprint input card 10 by determining whether the two images matched match or not based on the result of matching by the matching unit 36. .

Next, the operation of the personal identification system configured as described above will be described. In using this personal identification system, a unique ID number is assigned to each person to be identified in advance, and the fingerprint input card 10 corresponding to each of the unique ID numbers assigned to the individual is carried on the portable device. Let it be. The server computer 3 associates each individual's fingerprint with each of the ID numbers.
0 is stored in the reference data storage unit 34.

When this personal identification system is used,
First, the fingerprint input card 10 carried by each individual is mounted on the fingerprint detector 20. In this state, the multi-stage prism 1
When the fingertip F is brought into close contact with the first detection surface 11a, the switch 13 detects this and the illumination device 21 irradiates the multi-stage prism 11 with reference light in response to the detection. The reference light is irregularly reflected in the multi-stage prism 11 and becomes light having components in all directions. At this time, light in a certain direction is transmitted to the detection surface 11a.
Is absorbed by the fingertip F at the position of the fingertip F in contact with the fingertip F, ie, at the ridge position of the fingerprint of the fingertip F, and is totally reflected at the position apart from the fingertip F, ie, the fingerprint groove line position of the fingertip F. I do. Therefore, an image representing the fingerprint of the fingertip F is formed by the reflected light from the detection surface 11a.

The reflected light from the detection surface 11a passes through each inclined surface 11b of the multi-stage prism 11, and the ID given to the fingerprint input card 10 by the shadow mask 12
After being blocked by the pattern representing the number, the image is formed on the image receiving device 23 by the lens 22. Thereby, the image receiving device 2
3 reads an image in which parallel lines of the above pattern are superimposed on a fingerprint image of the fingertip F, as shown in FIG. Then, the image including the fingerprint and the parallel lines read by the image receiving device 23 is converted into data by the CPU 24 and is output to the output unit 2.
5 to the server computer 30.
At this time, information indicating the position of the fingertip F on the detection surface 11a of the multi-stage prism 11 is acquired from the image by the CPU 24, and data indicating the position information is also output to the output unit 2.
5 to the server computer 30.

The server computer 30 is connected to the output unit 2
When each data is output in step 5, the data representing the output image is first stored in the received image storage unit 31. At this time,
The relative position calculation unit 32 determines, based on the position information output from the output unit 25, a portion representing the fingerprint of the fingertip F in the image stored in the received image storage unit 31 and a portion blocked by the shadow mask 12. Is calculated. On the other hand, the ID extraction unit 33
The ID number assigned to the used fingerprint input card 10 is extracted by recognizing the pattern of the portion blocked by the shadow mask 12 from the image stored in the. After the extraction, the image generation unit 35 reads out the data corresponding to the extracted ID number from the data stored in the reference data storage unit 34 and stores the data in the fingerprint image represented by the data. Data representing an image in which parallel lines of the pattern recognized by the ID extraction unit 33 are superimposed at the relative position calculated by the relative position calculation unit 32 is generated.

After the data is generated by the image generation unit 35, the collation unit 36 collates the image stored in the received image storage unit 31 with the image generated by the image generation unit 35. Then, the determination unit 37 determines whether or not the two images matched with each other match or not based on the matching result by the matching unit 36, and determines whether or not to authenticate the individual using the fingerprint input card 10. This determination result is output to a system (not shown), and is used for, for example, permission and prohibition control such as opening and closing of a door and use of a terminal.

As described above, in the fingerprint input device in the above embodiment, the detection surface 11a of the multi-stage prism 11
A part of the reflected light from the camera is blocked by the shadow mask 12 in a predetermined unique pattern before reaching the image receiving device 23. The image read by the image receiving device 23 includes the fingerprint of the fingertip F and the unique And the ID number as unique data for each individual are input at the same time, which is convenient. In addition, since the plate-shaped multi-stage prism 11 is employed, the configuration can be reduced in size.

Further, since the shadow mask 12 is formed in a three-dimensional plate shape having a plurality of through holes 12a and it is difficult to accurately reproduce the shadow mask 12, it is difficult to illegally duplicate the shadow mask 12. And security is kept high. Also, the through hole 1 of the shadow mask 12
2a are formed so as to be inclined with respect to the thickness direction of the shadow mask 12, and only light reflected from the detection surface 11a of the multi-stage prism 11 reaches the image receiving device 23 by setting the thickness of the shadow mask 12. Therefore, it is possible to secure the reading accuracy of the image receiving device 23 after setting the optical path from the multi-stage prism 11 to the image receiving device 23 to be short, and to reduce the configuration.

Also, since the multi-stage prism 11 and the shadow mask 12 are integrally formed as a fingerprint input card 10 in a card shape, each individual can carry the shadow mask 12 corresponding to the assigned ID number. Thus, the usability of the fingerprint input device is good.

In the personal identification system using the fingerprint input device, the image generation unit 35 of the server computer 30 uses the image receiving device 23 of the fingerprint input device from the data stored in the reference data storage unit 34. The data corresponding to the pattern included in the image read by the device and blocked by the shadow mask 12 is read out to generate an image, and the collation unit 36 determines the image read by the image receiving device 23 and the image generation unit 35. Check with the generated image. Therefore, the data to be collated by the collation unit 36 from the data stored in the reference data storage unit 34 is specified in advance based on the pattern blocked by the shadow mask 12, and the time required for the collation is accordingly determined. It is shortened. Further, also in this case, since the fingerprint of the individual and the pattern are simultaneously inputted to the fingerprint input device, the usability of the personal identification system is kept high.

B. Second Embodiment Next, a second embodiment of the present invention will be described with reference to the drawings. In this embodiment, as shown in FIG. 5, the fingerprint input card 10 and the fingerprint detector 20 of the fingerprint input device according to the first embodiment are integrally carried together.

This fingerprint input device has a rectangular parallelepiped (about 1 mm to 2 cm thick) casing 40 containing the same multi-stage prism 11, shadow mask 12, switch 13, illumination device 21, CPU 24, and output unit 25 as described above. Have. The lens 22 employed in the first embodiment is omitted for the sake of miniaturization of the device, and the image receiving device 41 having a larger image receiving area than the image receiving device 23 employed in the first embodiment is correspondingly used. I am trying to adopt it.

In the fingerprint input device according to the second embodiment configured as described above, since each individual can carry the shadow mask 12 corresponding to the assigned ID number, the usability of the fingerprint input device is good. It has become.

In each of the above embodiments, the CPU 24 of the fingerprint input device and the relative position calculator 32 of the server computer 30 are cut off by the shadow mask 12 from the portion representing the fingerprint in the image read by the image receiving device 23. Calculate the relative positional relationship with the part, and
When the image is generated by the reference numeral 5, the relative position relationship calculated is taken into account to prevent the portion of the fingerprint image hidden by the parallel lines from affecting the collation by the collation unit. However, the interval between the through holes 12a of the shadow mask 12 is generally set to an interval (for example, 50 μm) that does not hide the ridges and groove lines of the fingerprint, and the shadow mask 12 of the fingerprint image is set. The portion cut off by the CPU 2 does not affect the collation.
4 and the calculation of the relative position by the relative position calculator 32 may be omitted.

Further, in each of the above embodiments, the acquisition of the position information of the fingertip F from the image read by the image receiving device 23 is executed by the CPU 24 of the fingerprint input device. The program may be executed by the computer 30. In this case, the CPU 24 of the fingerprint input device only needs to execute the process of converting the image into data. As for the data conversion, the CPU 24 simply converts the image data into image data representing the image itself, and the server computer 30 further converts the image data into data representing the characteristic points of the fingerprint. It may be.

Conversely, in the above embodiment, the relative positional relationship between the portion representing the fingerprint and the portion blocked by the shadow mask 12 in the image read by the image receiving device 23 is calculated, and the ID from the image is calculated. The number extraction is performed by the relative position calculation unit 32 and the ID extraction unit 33 of the server computer 30, respectively. However, the calculation of the relative position relationship and the extraction of the ID number are also performed by the CP of the fingerprint input device.
The processing may be executed in U24.

[Brief description of the drawings]

FIG. 1 is a schematic diagram of a fingerprint input device according to a first embodiment of the present invention.

FIG. 2 is an enlarged vertical sectional view of a multi-stage prism and a shadow mask of FIG.

FIG. 3 is an overall block diagram of a personal identification system using the fingerprint input device.

FIG. 4 is an explanatory diagram showing an example of an image read by the image receiving device of FIGS.

FIG. 5 is a schematic diagram of a fingerprint input device according to a second embodiment of the present invention.

[Explanation of symbols]

10: fingerprint input card, 11: multi-stage prism, 11a ...
Detection surface, 11b: inclined surface, 12: shadow mask, 12
a: through hole, 20: fingerprint detector, 21: lighting device, 23
... image receiving device, 30 ... server computer, 33 ... ID extraction unit, 34 ... reference data storage unit, 35 ... image generation unit,
36: collating unit, F: fingertip.

Continued on the front page (71) Applicant 000003551 Tokai Rika Electric Machinery Co., Ltd. 3-260, Toyota, Oguchi-machi, Niwa-gun, Aichi Prefecture (71) Applicant 000003207 Toyota Motor Corporation Toyota-cho, Toyota-shi, Aichi Prefecture 1-71 000006013 Mitsubishi Electric Corporation 2-3-2 Marunouchi, Chiyoda-ku, Tokyo (71) Applicant 390040187 Melco Co., Ltd. 4-110-11 Osu, Naka-ku, Nagoya-shi, Aichi (71) Applicant 000006932 Ricoh Elemex Corporation Nagoya (2-1) Inventor Toshio Fukuda 2-66 Yada-cho, Higashi-ku, Nagoya-shi, Aichi Prefecture, Japan 2-66, Yata-cho, Aichi Prefecture 122 (72) Inventor, Fumito Arai 6-Aoyagi-cho, Chikusa-ku, Nagoya, Aichi 5-1 Mates Chigusa Aoyagi 501 (72) Inventor Jiro Tsuruno 1-36-1 Kawasaki-cho, Chigusa-ku, Nagoya-shi, Aichi Prefecture Miyukiso Room 7 (72) Inventor Koichi Itoigawa 3-260 Toyota, Oguchi-machi, Nishi-gun, Aichi Prefecture F-term in Tokai Rika Electric Works (reference 4C038 FF01 FF05 FG01 5B043 AA09 BA02 DA05 FA02 GA02 5B047 AA25

Claims (8)

[Claims] 1. A prism having a detection surface formed of a transparent body and having a fingertip in close contact with the detection surface, an inclination surface disposed at a predetermined angle to the detection surface, and passing reflected light from the detection surface. A fingerprint inputting means for irradiating the prism with reference light reflected on the detection surface, and an image receiving means for reading an image formed by reflected light from the detection surface passing through the inclined surface of the prism; In the apparatus, a blocking unit interposed between the inclined surface of the prism and the image receiving unit and blocking a part of the reflected light from the detection surface that has passed through the inclined surface of the prism in a predetermined unique pattern. A fingerprint input device, comprising: 2. The fingerprint input device according to claim 1, wherein said prism comprises a multi-stage prism having a plurality of said inclined surfaces. 3. The fingerprint input device according to claim 1, wherein the blocking unit allows the reflected light from the detection surface that has passed through the inclined surface of the prism to pass to the image receiving unit. A fingerprint input device comprising a plate-like member provided with a plurality of optical paths. 4. The fingerprint input device according to claim 3, wherein a plurality of optical paths of said plate-shaped member are formed to be inclined with respect to a thickness direction of said plate-shaped member. 5. The fingerprint input device according to claim 1, wherein said prism and said blocking means are integrally formed in a card shape. . 6. The fingerprint input device according to claim 1, wherein said prism, image receiving means, irradiating means, and blocking means are housed in a same casing. Characteristic fingerprint input device. 7. A personal identification system using a fingerprint input device according to any one of claims 1 to 6, wherein data representing a fingerprint as personal information is blocked by said fingerprint input device. Storing means associated with the pattern to be cut off, and among the data stored in the storing means, included in the image read by the image receiving means of the fingerprint input device and blocked by the blocking means A personal identification system, comprising: reading means for reading data corresponding to a pattern; and matching means for checking data read by the reading means and data representing an image read by the image receiving means. . 8. A plate-shaped fingerprint input card to be mounted on a fingerprint detector provided with an irradiating means and an image receiving means, wherein said fingerprint input card is mounted on said fingerprint detector. A detection surface that reflects the reference light emitted by the irradiating means on the back side while the fingertip is in close contact with the front side, and is disposed at a predetermined angle to the detection surface and reflected from the detection surface. A prism having an inclined surface through which light passes, and blocking means for blocking a part of the reflected light from the detection surface reaching the image receiving means through the inclined surface of the prism in a predetermined unique pattern. A fingerprint input card characterized by being provided.