JPS63678A - Fingerprint sensor - Google Patents

Abstract

PURPOSE:To decrease the number of holograms, and to miniaturize a light transmissive plate by receiving a light beam scattered in the lower side of the light transmissive plate, by a photosensor, and deriving the deviated position of a finger by its output. CONSTITUTION:Within the critical angle of the total reflection of the lower side of a light transmissive plate 31 of a fingerprint input part, a laser beam 32 reflected by a finger 12 is scattered to the outside from the light transmissive plate 31. This scattered light is received by a photosensor 33, the deviated position of the finger 12 is detected by an error detecting circuit 34, a position detection, etc., of a feature part are detected by a prescribed processing in a CPU 19, and a fingerprint collation is executed. In such a way, the scattered light from the light transmissive plate 31 being right under the fingerprint input part can be utilized, therefore, a hologram for detecting an error is eliminated and the light transmissive plate 31 also is miniaturized.

Description

[Detailed Description of the Invention] [Summary] An optical sensor is placed below the light guide plate of the fingerprint input section of the fingerprint sensor, and the optical sensor receives the light scattered within the critical angle of total reflection. Based on the output, an error detection circuit calculates the deviation amount of the finger position and performs fingerprint verification.

In addition, an optical sensor is placed below the light guide plate of the fingerprint input part of the fingerprint sensor to receive the light scattered within the critical angle of total reflection, and the level of the image signal is made uniform by the output of the optical sensor. image input to eliminate individual differences.

[Industrial application field]

The present invention relates to a flat-plate fingerprint sensor with total internal reflection illumination, and more specifically, to a fingerprint sensor that uses an optical sensor to detect scattered light from a finger as information, which can be used for fingerprint verification, etc. It is something.

[Traditional technique]

Generally, a total internal reflection illumination type flat fingerprint sensor is used to perform fingerprint verification and the like. This fingerprint sensor is
For example, as shown in FIG. 5, a device 12 is brought into contact with a fingerprint input section on the upper center of a light guide plate 11 made of a flat glass plate or the like, and the light guide plate 11 is illuminated with a laser beam 13 from below. Of this laser beam 13, the reflected light from the ridges 12a of the finger 12 (crests forming a fingerprint) undergoes total internal reflection, is transmitted to the hologram 14 provided on the lower surface of the light guide plate 11 at a predetermined position, and is taken out to the outside. It will be done. This light taken out to the outside is received by the CCD 15 and stored in the frame memory 17 via the A/D converter 16.

The frame memory 17 is connected to a CPU 19 via a bus 18, and the CPU 19 performs comparison with already registered fingerprints and the like. For this verification, it is necessary to correct the bias in the contact position of the finger 12 on the fingerprint input section on the light guide plate 11 and to detect the center position of the image of the finger on the CCD 15. This image center position can be detected by software processing using predetermined logic, but it takes time to verify. Therefore, the light totally reflected from the finger 12 by the light guide plate 11 is guided to another position, and a hologram 20 for error detection is provided on the lower surface of the light guide plate 11 to take it out to the outside. This light taken out to the outside is received by a four-division diode 21, and an error detection circuit 22 determines the amount of deviation from the center of the image. The error detection circuit 22 is connected to the CPU 19 by the bus 18.
, and fingerprint verification is performed through predetermined processing. This hardware support speeds up the overall verification process.

Further, as shown in FIG. 6, the finger 12 is brought into contact with the fingerprint input section on the upper surface of the light guide plate 11 made of a flat glass plate, etc.
The light guide plate 11 is illuminated with a laser beam 13 from below. finger 1
2 comes into contact with the upper surface of the light guide plate 11 at its ridges (crests forming fingerprints) 12a, and optical contact is formed by the moisture (water or oil) on the surface of the ridges 12a. Therefore, the light reflected from the ridge 12a of the finger 12 out of the laser light 13 undergoes repeated total reflection and is extracted to the outside by the hologram 14 provided on the lower surface of the light guide plate 11 at a predetermined position.

This light taken out to the outside is received by the CCD 15,
The data is stored in the frame memory 17 via the A/D converter 16. Frame memory 17 is connected to CPU 19 by bus 18.
The image signal is captured by the freeze signal S of the CPU. Then, the CPU 19 performs a comparison with already registered fingerprints and the like.

[Problem that the invention seeks to solve]

However, such a fingerprint sensor requires a hologram 20 for error detection, and a large light guide plate 11 must be used for this purpose.

In addition, in such a fingerprint sensor, the light guide 1. i
There are individual differences in the optical contact to ll, and the analog signal of the CCD 15 has high and low levels, so it is necessary to use an A/D converter 16 with a wide range and a frame memory 17 with a large capacity. , subsequent processing was complicated.

The present invention was created in view of these points, and it allows the number of holograms to be reduced and the light guide plate to be made smaller.
The present invention aims to provide a fingerprint sensor that can be simplified.

Another purpose is to keep the image signal level within a predetermined range without being affected by individual differences, to enable the use of low A/D converter ranges, low-capacity frame memories, etc., and for post-processing. The purpose of the present invention is to provide a fingerprint sensor that is easy to use.

[Means for solving problems]

FIG. 1 shows an explanatory diagram of the principle of the fingerprint sensor of the present invention.

In FIG. 1, 31 is a flat light guide plate, 12 is a finger touching the fingerprint input part of the light guide plate 31, 32 is a laser beam irradiated to the finger 12 from below the light guide plate 31, 33 is a 4-divided diode, etc. 34 is an error detection circuit.

Further, FIG. 3 shows an explanatory diagram of the principle of the fingerprint sensor of the present invention.

In FIG. 3, 21 is a flat light guide plate, 12 is a finger that contacts the fingerprint input part of the light guide plate 21, 22 is a laser beam that illuminates the finger 12 from below the light guide plate 21, 23 is a light sensor, 2
4 is a comparator, and 17 is a frame memory.

[For production]

In FIG. 1, within the critical angle of total reflection on the lower side of the light guide plate 31 of the fingerprint input section, the laser beam 32 reflected by the finger 12
is scattered to the outside from the light guide plate 31.

This scattered light is received by the optical sensor 33, and the error detection circuit 3
4, the biased position of the finger 12 is detected.

Further, in FIG. 3, within the critical angle of total reflection on the lower side of the light guide plate 21 of the fingerprint input section, the laser beam 22 reflected by the finger 12 is scattered to the outside from the light guide plate 21. This scattered light has a certain correlation with the stiffness of the finger 12, and is received by the optical sensor 23. The output of this optical sensor 23 is compared with a predetermined value A by a comparator 24, and in response to the output signal S1 when the predetermined value A is exceeded, a freeze signal S is generated and the capturing of the image into the frame memory 17 is started.

〔Example〕

Embodiments of the present invention will be described in detail below with reference to the drawings.

FIG. 1 is a diagram explaining the principle of a fingerprint sensor according to a first embodiment of the present invention.

In this figure, the reference numeral 31 is a light guide plate made of a flat glass plate, etc., and the fingerprint input section is located at one end of the upper surface of the light guide plate 31). 1r12 are brought into contact with each other, and the light guide plate 31 is illuminated with laser light 32 from below. Finger 12 of this laser beam 32
The reflected light from the ridge 12a repeats total reflection and is extracted to the outside by the hologram 14 provided on the other end side of the lower surface of the light guide plate 31. This light taken out to the outside is transmitted to the CCD 15 and the A/D converter 1 as explained in the conventional example.
6 and stored in the frame memory F.

Frame memory 17 is connected to CPU 19 by bus 18.

Directly below the light guide plate 31 of the fingerprint input section with which the upper part 12 is brought into contact, a four-divided diode 33 is arranged as an optical sensor. This 4-division diode.

As shown in FIG. 2, the diode 33 has four divided light receiving areas 31a to 31d, into which the scattered light from the finger 12 of the laser beam 32 enters. connected to the same error detection circuit 34 as in the example,
The amount of deviation from the center of the image is determined by determining the sum or difference of the outputs of the light receiving areas 313 to 31d. The error detection circuit 34 is connected to the CPU 19 by the bus 18,
Fingerprint verification and the like are performed as part of the predetermined processing.

According to such a configuration, immediately below the light guide plate 31 of the fingerprint input section, the laser beam 32 reflected by the finger 12 is scattered to the outside from the light guide plate 31 within a range within the critical angle of total reflection. This scattered light is received by the four-division diode 33, and the error detection circuit 34 can detect the deviation position of the center position of the image of the finger on the CCD 15. As a result, the CPU 19 performs predetermined processing to detect the position of the characteristic part and perform fingerprint verification.

Therefore, since the scattered light from the light guide plate 31 directly below the fingerprint input section can be used, a hologram for error detection is not necessary.
Light guiding f! 31 will also become smaller.

FIG. 3 is a diagram illustrating the principle of a fingerprint sensor according to a second embodiment of the present invention.

In this figure, reference numeral 21 denotes a light guide plate made of a flat glass plate, etc., and the finger 12 is brought into contact with the fingerprint input section on one end side of the upper surface of the light guide plate 21, and the laser beam 22 is irradiated from below the light guide plate 21. . Of this laser light 22, the light reflected by the ridge 12a of the finger 12 undergoes repeated total reflection and is extracted to the outside by the hologram 14 provided on the other end side of the lower surface of the light guide plate 21. This light taken out to the outside is stored in the frame memory 17 via the CCD 15 and the A/D converter 16 as described in the conventional example.

Frame memory 17 is connected to CPU 19 by bus 18.

An optical sensor 23 is arranged directly below the light guide plate 21 of the fingerprint input section with which the upper part 12 is brought into contact.

This optical sensor 23 receives scattered light within the critical angle of total reflection of the laser 2i. The scattered light has a proportional relationship with the total reflected light, and has a certain correlation with the tightness of the finger 12. The output of the optical sensor 23 is input to a comparator 24. This comparator 24 compares the output signal of the optical sensor 23 with a predetermined default value A, and
When the output signal of No. 3 becomes higher than a predetermined value A, an output signal S1 is generated. The default value A is selected so that the luminance signal level of the CCD 15 falls within a predetermined range. The output of the comparator 24 is connected to the input terminal of an AND gate circuit 25. The other input terminal of the AND gate circuit 25 is connected to the CPU 19 via the bus 18, and receives the image capture start signal S2. The output of the AND gate circuit 25 generates a freeze signal S and the frame memory 17
is output to. That is, the comparator 24 and the AND gate circuit 25 constitute a signal generation circuit for capturing an image into the frame memory 17.

According to such a configuration, immediately below the light guide plate 21 of the fingerprint input section, the laser beam 22 reflected by the finger 12 is scattered outward from the light guide plate 21 within a range within the critical angle of total reflection. This scattered light has a predetermined relationship with the intensity of light that is totally reflected, extracted from the hologram 14, and received by the CCD 15. When the output of the optical sensor 23 is higher than the predetermined value A, an output signal S1 is generated, and this signal S1 and the image capturing start signal S2 generate a freeze signal S and the frame memo IJ is generated.
17 images are captured. This allows the entire screen to be at the same level regardless of individual differences.

Therefore, by utilizing the scattered light from the light guide plate 21 directly below the fingerprint input section, an A/D converter, a frame memory, etc. with a narrow range can be used, and subsequent processing is also simplified.

FIG. 4 is a diagram illustrating the principle of a fingerprint sensor according to another embodiment of the present invention.

In this embodiment, a comparator 31 is provided after the CCD 15, and the output of the optical sensor 23 similar to that of the previous embodiment is sent to the comparator 31 via a counting circuit 32. The output of this comparator 31 is connected to the frame memory 17, and an image is captured in response to a freeze signal S from the CPU.

According to such a configuration, the analog signal from the CCD 15 can be directly binarized.

In addition, in the first embodiment, the four-division diode 3
3 is used, however, any optical sensor that detects the bias base can be used, and for example, it may be divided into two and detect only the bias in one direction.

Further, the optical sensor may be disposed at least within a critical angle of total reflection in which the reflected light from the finger 12 is scattered outside the light guide Fi 31.

〔Effect of the invention〕

As described above, according to the present invention, the light scattered below the light guide plate is received by the optical sensor, and the deviation and position of the finger is determined from the output thereof, so the number of holograms can be reduced. At the same time, the light guide plate can also be made smaller, which has the effect of simplifying the structure.

Further, according to the present invention, when the output of the light receiving sensor disposed below the light guide plate of the fingerprint input section of the flat fingerprint sensor exceeds a predetermined value, an image capture signal is generated, and this signal is used to input the fingerprint image. Since a signal generation circuit is provided to start the process, the image signal level can be kept within a predetermined range without being affected by individual differences, and A/D converters, frame memories, etc. with narrow ranges can be used. This has the effect of simplifying subsequent processing.

[Brief explanation of drawings]

Fig. 1 relates to the first embodiment of the present invention and is an explanatory diagram of the principle of a fingerprint sensor. Fig. 2 is an explanatory diagram of a 4-division diode. Fig. 3 relates to the second embodiment of the present invention and is an explanatory diagram of the principle of the fingerprint sensor. 4 is a diagram explaining the principle of a fingerprint sensor according to another embodiment of the present invention. FIG. 5 is a diagram explaining the principle of a conventional fingerprint sensor. FIG. 6 is a diagram explaining the principle of a conventional fingerprint sensor. It is. 12...Finger, 14...Hologram, 15...COD. 16... A/D converter, 17... Frame memory, 18... Bus, 19... CPU. 21... Light guide plate, 22... Laser light, 23... Optical sensor, 24... Comparator, 25... AND gate circuit, 31... Light guide plate, 32... Laser light, 33 ... Optical sensor (four-division diode), 34...
Error detection circuit. Patent Applicant: Fujitsu Ltd. Bu4su@77212E1
9' Go) 1 "Iode's Famous Dinner - Sun, Moon," Part 2
Figure 3, t-4 Ginp month. This is a picture of the shogi Satomi, who is as talented as Awaotomeji and Seida.

Claims (1)

[Claims] 1) An optical sensor (33) is disposed below the light guide plate (31) of the fingerprint input section of the total internal reflection illumination type flat fingerprint sensor, and the detection output from the optical sensor (33) A fingerprint sensor characterized by being provided with an error detection circuit (34) for detecting a biased position of a finger. 2) An optical sensor (23) is arranged below the light guide plate (21) of the fingerprint input section of the total internal reflection illumination type flat fingerprint sensor, and when the output of this optical sensor (23) exceeds a predetermined value, an image is displayed. A fingerprint sensor comprising a signal generation circuit that generates a capture signal, and starts inputting a fingerprint image based on this signal.