JP2002083289A - Fingerprint collation device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To accurately detect a fingerprint image of a person's fingertip having individual differences, such as a dry skin or a fatty skin. SOLUTION: In this collation device, when an IC card 2 is inserted into an IC card reader 1, the IC card reader 1 reads a waiting time, parameters and fingerprint data specific to the user from the IC card 2, sets the parameters peculiar to the user to an A/D converting part 11B of a sensor chip 11, and sets the waiting time specific to the user to a timer 12A. When a finger 3 of the user is pressed against the sensor chip 11, the timer 12A is started, and the sensor chip 11 is started after a time of the timer 12A is up, to detect a fingerprint of the finger 3. The fingerprint data detected by the sensor chip 11 are collated with the fingerprint data from the IC card 2 to identify the user.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[0001] 1. Field of the Invention [0002] The present invention relates to a fingerprint collating apparatus for collating fingerprint data registered in advance with fingerprint data detected by a semiconductor capacitive sensor.

[0002]

2. Description of the Related Art A semiconductor capacitive sensor used in a fingerprint collating device of this type detects a concave and convex portion of a human fingerprint as a capacitance difference and generates a grayscale image. When authenticating a user using a fingerprint, the fingerprint matching device registers the fingerprint data of the user in advance. Then, when a user's finger is imprinted on the semiconductor capacitive sensor, the unevenness of the fingerprint of the user is detected as a fingerprint image based on the capacitance difference of the capacitive sensor as described above. , And compares the generated fingerprint data with the registered fingerprint data. If the two match, the user is identified as the user.

[0003]

Generally, human fingertips have individual differences such as dry skin and oily skin. In a conventional fingerprint collation device, since a semiconductor capacitive sensor detects a fingerprint image of a human fingertip having such individual differences under the same conditions irrespective of individual differences, an accurate fingerprint image required for collation can be obtained. There was a problem that it could not be obtained. Therefore, an object of the present invention is to perform accurate detection when detecting a fingerprint image of a human fingertip having individual differences such as dry skin or oily skin.

[0004]

SUMMARY OF THE INVENTION In order to solve the above problems, the present invention includes a capacitive sensor chip made of a semiconductor for detecting a fingerprint, fingerprint image data of a user, and parameters of the capacitive sensor chip. A storage unit for storing personal information, a fingerprint matching unit for comparing fingerprint image data detected by the capacitive sensor chip with fingerprint data of the storage unit, and setting parameters of the storage unit for the capacitive sensor chip A setting unit, and a control unit that activates the capacitive sensor chip and detects fingerprint image data after setting the parameters to the capacitive sensor chip by the setting unit. The fingerprint matching unit includes a capacitive sensor chip of the control unit. After the activation, the fingerprint image detected by the capacitive sensor chip is compared with the fingerprint data in the storage unit to perform fingerprint authentication. In addition, the storage unit stores a waiting time at the time of detecting a fingerprint image of the capacitive sensor chip as personal information, and includes a detection unit that detects contact of a finger with the capacitive sensor chip,
The control section activates the capacitive sensor chip after the waiting time of the storage section has elapsed after the detection section detects the finger contact, and starts the detection of the fingerprint image. In addition, a storage unit for storing personal information is provided on the IC card, and an IC card reader for reading data of the IC card is provided with a capacitive sensor chip, a fingerprint matching unit, a setting unit, a control unit, and a detection unit. .

[0005]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described below with reference to the drawings. FIG. 1 is a block diagram showing the configuration of the fingerprint matching device according to the present invention. This fingerprint collation device includes an IC card reader 1 and an IC card 2 as shown in FIG. The IC card reader 1 inputs a semiconductor capacitive sensor chip (hereinafter, sensor chip) 11 for detecting a fingerprint of the finger 3 imprinted by a user, and fingerprint image data detected by the sensor chip 11 to perform predetermined processing. , A memory 13 for storing fingerprint image data input by the control unit 12, and a display unit 1 for performing various displays.
4 and an interface 15 with the IC card 2.

[0006] The sensor chip 11 includes a sensor section 11A,
An A / D conversion unit 11B that digitizes the fingerprint image detected by the sensor unit 11 and outputs the digitized fingerprint image to the control unit 12 as fingerprint image data. Further, the control unit 12 includes a timer 12
A is built in. Further, the IC card 2 has an interface 21 with the IC card reader 1 and a memory 22 for registering fingerprint image data of the user.

When the user's finger 3 is imprinted, the sensor section 11A of the sensor chip 11 constituting the IC card reader 1 has a capacitance difference corresponding to the unevenness of the skin surface of the contacted finger 3 (ie, fingerprint). And outputs it as a voltage signal.
The voltage signal output from the sensor 11A is converted into a digital signal by the A / D converter 11B as described above, and is output to the controller 11 as fingerprint image data.

FIGS. 2 and 3 show the structure of the sensor section 11A in the sensor chip 11 described above. Sensor unit 11
A is composed of a plurality of sensors 4 arranged in a grid as shown in FIG.
As shown in FIG. 7, the detection circuit 41 includes a detection element 41 which is a capacitance element, a signal generation circuit 42, a signal amplification circuit 43, and an output circuit 44. When the finger 3 comes into contact, a capacitance difference is generated in the detection element 41 of each sensor 4 according to the unevenness of the skin surface of the contacted finger 3. Output circuit 44
Is output to the A / D converter 11B.

The A / D converter 11B constituting the sensor chip 11 converts an analog voltage level (analog value) output from the output circuit 44 of the sensor 4 into a digital value. The corresponding relationship between the analog value and the digital value changes according to. As parameters set in the A / D conversion unit 11B, parameter values A and B as shown in FIG. 4 are set.

If the analog value input to the A / D converter 11B is lower than the set parameter value (A + B), it is assumed that a black black fingerprint image of gradation 0 can be obtained from the A / D converter 11B. I do. Further, the analog value input to the A / D converter 11B is equal to the set parameter value (A + (25
5 × B)), the gray level 2 is output from the A / D converter 11B.
It is assumed that 55 pure white fingerprint images can be obtained. Further, the analog value input to the A / D converter 11B is equal to or more than the parameter value (A + n × B) and the parameter value (A +
If the level is lower than (n + 1) B), the A / D converter 11
It is assumed that a fingerprint image of gradation n can be obtained from B.

As described above, when the parameter value A is set to a large value, the fingerprint image obtained from the A / D conversion unit 11B becomes black, and when the parameter value A is set to a small value, the A / D conversion unit 11B becomes black.
The fingerprint image obtained from B becomes white. When the parameter value B is set to a large value, the resolution of the fingerprint image obtained from the A / D conversion unit 11B becomes coarse, and when the parameter value B is set to a small value, the resolution of the fingerprint image obtained from the A / D conversion unit 11B becomes fine. Become. Thus, the A / D converter 11B
A / D conversion unit 11B
The brightness and the resolution of the fingerprint image obtained from can be changed. Therefore, when a fingerprint image of a human fingertip having individual differences such as dry skin or oily skin is detected, by setting a parameter value corresponding to such individual differences in the A / D conversion unit 11B, A / D conversion is performed. An accurate fingerprint image that is not affected by the individual difference as described above can be output from the D conversion unit 11B.

FIG. 5 is a flowchart showing the operation of the main part of the fingerprint collating apparatus, showing the operation of reading a fingerprint by the sensor chip 11. The operation of the main part of the present invention will be described in detail according to this flowchart. by the way,
User-specific fingerprint image data is registered in the memory 22 of the IC card 2, and the user-specific parameter values A and B set in the A / D converter 11B in the sensor chip 11 described above. And the waiting time until the A / D conversion unit 11B starts the conversion operation is registered and stored as the personal information of the user.

Such an IC card 2 is used by a user for an IC card.
When the IC card reader 1 is inserted into the card reader 1, the control unit 12 of the IC card reader 1
The user's fingerprint image data, parameter values, and waiting time are read from the memory 22 and stored in the memory 13. Next, the control unit 12 sets the parameter value to the A / D conversion unit 11B via the signal line a shown in FIG. 1 in step S2 and sets the waiting time in step S3 to the timer 12
Set to A.

Next, the control unit 12 determines whether or not the user's finger 3 has been imprinted on the sensor unit 11A in the sensor chip 11 via the signal line b shown in FIG.
When the impression of the finger 3 is detected, the timer 12A is determined in step S5.
Start Then, it is determined in step S6 whether or not the timer 12A has timed out. When the timer 12A has timed out, the A / D converter 11B is activated via the signal line c shown in FIG. 1 in step S7.

Thereafter, the control section 11 sequentially reads the fingerprint image data detected by the sensor section 11A and digitized by the A / D conversion section 11B in step S8, sequentially stores them in the memory 13, and stores all the fingerprint image data. When the reading is completed and the determination in step S9 becomes "Y", the fingerprint image data stored in the reading memory 13 from the sensor chip 11 is compared with the fingerprint image data stored in the reading memory 13 from the memory 22 of the IC card 2. The processing is performed in step S10.

Then, the quality of the result of the collation processing is determined in step S11. The fingerprint image data read from the sensor chip 11 and the fingerprint image data read from the IC card 2 match, and the determination in step S11 is "Y". Then, in step S12, a personal identification result indicating "personal authentication" is output and displayed on the display unit 14.

As described above, when a fingerprint image of a human fingertip having individual differences, such as dry skin or oily skin, is detected, parameter values corresponding to such individual differences are set in the A / D converter 11B. With this configuration, an accurate fingerprint image that is not affected by individual differences as described above can be converted into an A / D converter 11.
B. Further, when detecting a fingerprint image of a fingertip of a human finger having individual differences, the detection waiting time of the sensor chip 11 is set according to the individual differences as described above. It is possible to obtain a more accurate fingerprint image which is not affected by the above.

[0018]

As described above, according to the present invention, a capacitive sensor chip made of a semiconductor for detecting a fingerprint and storage for storing personal information including fingerprint image data of a user and parameters of the capacitive sensor chip. Unit, a fingerprint matching unit that compares fingerprint image data detected by the capacitive sensor chip with fingerprint data of the storage unit, and a setting unit that sets parameters of the storage unit for the capacitive sensor chip. After setting the parameters to the capacitive sensor chip by the unit, the capacitive sensor chip is activated to detect the fingerprint image data, so that there is a difference between each person such as dry skin and oily skin When detecting a fingerprint image, parameters corresponding to such individual differences are set in the capacitive sensor chip. Not affected, it is possible to output an accurate fingerprint image. In addition, the storage unit stores the waiting time when detecting the fingerprint image of the capacitive sensor chip as personal information, and includes a detecting unit that detects the contact of the finger with the capacitive sensor chip. After the detection, the capacitive sensor chip is activated after the elapse of the waiting time in the storage unit, and the detection of the fingerprint image is started.Therefore, when detecting the fingerprint image of a human fingertip having individual differences, as described above. Since the detection waiting time of the capacitive sensor chip is set according to the individual difference, it is possible to output a more accurate fingerprint image from the capacitive sensor chip without being affected by such individual differences. In addition, a storage unit for storing personal information is provided on the IC card,
Since the capacitive sensor chip, the fingerprint collating unit, the setting unit, the control unit, and the detecting unit are provided in the IC card reader that reads the data of the C card, each user can accurately manage and store his or her personal information.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a configuration of a fingerprint matching device according to the present invention.

FIG. 2 is a diagram showing a configuration of a fingerprint sensor unit in a semiconductor capacitive sensor chip of the fingerprint collation device.

FIG. 3 is a block diagram showing a configuration of one detection unit in the semiconductor capacitive sensor chip.

FIG. 4 is a diagram showing the status of parameters set in an A / D converter in the semiconductor capacitive sensor chip.

FIG. 5 is a flowchart showing an operation of a main part of the fingerprint matching device.

[Explanation of symbols]

1 ... IC card reader, 2 ... IC card, 3 ... finger, 4 ...
Sensor, 11: semiconductor capacitive sensor, 11A: sensor unit, 11B: A / D converter, 12: control unit, 12A: timer, 13, 22: memory, 14: display unit, 15, 21
... Interface, 41 ... Detection element, 42 ... Signal generation circuit, 43 ... Signal amplification circuit, 44 ... Output circuit.

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Yukio Okazaki 2-3-1 Otemachi, Chiyoda-ku, Tokyo Nippon Telegraph and Telephone Corporation (72) Inventor Hiroki Morimura 2-3-3, Otemachi, Chiyoda-ku, Tokyo No. 1 Within Nippon Telegraph and Telephone Corporation (72) Inventor Riki Yamaguchi 2-3-1, Otemachi, Chiyoda-ku, Tokyo F-Term within Nippon Telegraph and Telephone Corporation (reference) 4C038 FF01 FF05 FG00 5B047 AA25 BA02 BB10 CA04 CB15 CB17 DB01

Claims (3)

[Claims] 1. A capacitive sensor chip made of a semiconductor for detecting a fingerprint, a storage unit for storing user's fingerprint image data and personal information including parameters of the capacitive sensor chip, and detection by the capacitive sensor chip. A fingerprint collating unit for collating the obtained fingerprint image data with the fingerprint data of the storage unit; a setting unit for setting parameters of the storage unit for the capacitive sensor chip; and the capacitive sensor chip by the setting unit A control unit that activates the capacitive sensor chip and detects the fingerprint image data after setting the parameter to the fingerprint sensor unit. A fingerprint matching device, wherein fingerprint authentication is performed by comparing a fingerprint image detected by a chip with fingerprint data in the storage unit. 2. The detection unit according to claim 1, wherein the storage unit stores a waiting time at the time of detecting a fingerprint image of the capacitive sensor chip as the personal information, and detects contact of a finger with the capacitive sensor chip. The control unit, after the contact of the finger is detected by the detection unit, after the elapse of the waiting time of the storage unit, activates the capacitive sensor chip to start detection of the fingerprint image, Fingerprint matching device. 3. The IC card according to claim 1, wherein the storage unit for storing the personal information is provided on an IC card, an IC card reader for reading data of the IC card is provided, and the capacity is stored in the IC card reader. A fingerprint collation device comprising a type sensor chip, the fingerprint collation unit, the setting unit, the control unit, and a detection unit.