JP3549795B2 - Fingerprint recognition integrated circuit - Google Patents

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a fingerprint recognition integrated circuit, and more particularly to a fingerprint recognition integrated circuit used as a fingerprint sensor in which a plurality of sensors for detecting unevenness of a fingerprint are spread on the integrated circuit.
[0002]
[Prior art]
With the progress of the information society and the environment of the modern society, interest in security technology is increasing. For example, in the information-oriented society, personal authentication technology for system construction such as electronic cashing is becoming an important key. In addition, research and development on authentication technology for protection against theft and unauthorized use of cards is being actively conducted (for example, Yoshimasa Shimizu et al., IC card with personal authentication function, IEICE Technical Report of IEICE, OFS92-32, p25-30 (1992)).
There are various authentication methods using fingerprints, voice prints, and the like for such unauthorized use protection measures. Among them, many technologies have been developed for fingerprint authentication technology. The fingerprint authentication method is broadly classified into an optical reading method and a method of detecting unevenness of a fingerprint by using electric characteristics of humans by replacing the unevenness of the fingerprint with an electric signal.
[0003]
The optical reading method is a method in which a fingerprint is captured as optical image data by using light reflection and a CCD image sensor and collation is performed (Japanese Patent Laid-Open No. 61-221883). As another method, a method using a piezoelectric thin film to read the pressure difference of a fingerprint of a finger has been developed (Japanese Patent Laid-Open No. 5-61965). Similarly, as a method of detecting the shape of a fingerprint by replacing the change in electrical characteristics caused by skin contact with the distribution of electric signals, an authentication method using a resistance change amount or a capacitance change amount using a pressure-sensitive sheet is used. It has been proposed (JP-A-7-168930). However, in the above-mentioned technologies, first, it is difficult to reduce the size of the system using light, it is difficult to use the system for general purposes, and there is a problem that the application is limited. Next, the method of sensing the unevenness of the finger using a pressure-sensitive sheet or the like is considered to be difficult to be put into practical use and to have poor reliability due to the special material and the difficulty in workability.
[0004]
Further, the conventional fingerprint reading apparatus is separated from the fingerprint recognizing apparatus, and the fingerprint sensor for detecting the shape of the fingerprint needs to output the read fingerprint data outside the reading apparatus. To address this, there is a method of scanning data detected by each pixel unit of the fingerprint sensor and outputting the data to the outside (for example, Teruhiko Tamori, JP-A-63-310087). However, in this method, fingerprint data is output for each data corresponding to one pixel unit. Therefore, when the number of pixel units of the fingerprint sensor increases, much time is required to output all fingerprint data. (For example, a few seconds). In such a state where much time is required, it may be difficult to promptly recognize the fingerprint of the user.
[0005]
On the other hand, in fingerprint recognition, it is necessary to collate a fingerprint image collected by a fingerprint sensor with fingerprint data of a user who has been registered in advance. As a fingerprint collation method, there are a method of extracting a feature point or the like of a fingerprint image and comparing it with a registered feature point, and a method of directly collating a fingerprint image with a registered image. Conventionally, a fingerprint recognition device composed of a microprocessor or the like has been used to realize this collation method. The above-described fingerprint recognition method requires processing with a large amount of calculation, such as creation and search of feature points or detection of a matching rate of images. Therefore, a high-performance processor is required, and the fingerprint recognition system is expensive. Therefore, it is difficult to apply the present invention to an object that needs to be inexpensive, such as an IC card or a portable device.
[0006]
When a fingerprint recognition system is constructed using these fingerprint reading devices and fingerprint recognition devices, the conventional fingerprint recognition system uses a fingerprint reading device 301 for collecting fingerprints and a fingerprint data of the user as shown in FIG. The fingerprint recognition device 303 outputs a recognition result by comparing it with fingerprint data in the registered database 302, and a processing device 304 that performs processing based on the recognition result.
[0007]
[Problems to be solved by the invention]
However, the configuration of the above-mentioned conventional fingerprint recognition system is large in the entire system, and cannot be applied to any location. In the configuration shown in FIG. 16, since each device is separated, the information is falsified at the time of data transfer between these devices, thereby making it possible to perform unauthorized recognition. In addition, in the configuration of FIG. 16, each device is separate, and the entire system becomes a large object. Therefore, it is difficult to mount fingerprint recognition on a small object such as an IC card or a portable device.
In addition, since each device is separated, there is a problem that information is falsified at the time of data transfer between these devices, and it becomes possible to perform unauthorized recognition.
[0008]
SUMMARY OF THE INVENTION The present invention has been made in view of the above points, and has as its object to provide a fingerprint recognition integrated circuit capable of forming a fingerprint recognition system on an integrated circuit chip and forming a very small fingerprint recognition system. I do.
[0009]
[Means for Solving the Problems]
FIG. 1 is a block diagram showing the principle of the present invention.
According to the present invention (claim 1), a plurality of pixels having a sensor circuit for converting unevenness due to a fingerprint into an electric signal are spread in an array, and a finger is brought into contact with the sensor means 1 for detecting the fingerprint of the finger as an electric signal. ,
A fingerprint memory 3 provided for each pixel or for each group of the pixels and for registering fingerprint data in advance;
Provided for each pixel or group of pixels, ShineFingerprint recognition means 2 for sending the combined result;
A data bus 4 for transferring the verification result sent by the fingerprint recognition means,
A counting means 5 connected to the data bus 4 for counting the total collation results sent to the data bus 4 and sending a write signal to the fingerprint recognition means;
The counting means 5 counts the matching results sent for each pixel or for each group of pixels.
Further, the present invention further includes a selector that switches and outputs a signal from a surrounding pixel or a group of the pixels and an output of the sensor unit 1 by a select signal from the counting unit 5,
The output of the selector is held by a write signal from the counting means 5 and a register for outputting data held in a peripheral pixel or a group of the pixels is compared with an output of the register and an output of the fingerprint memory. A pixel or a group of pixels having a second recognition circuit consisting of a matching circuit consisting of a second matching means for outputting the result of matching to the data bus 4 shifts the data held in an array by pixels or groups of pixels to the periphery, The collation results transmitted via the bus are totaled, and the fingerprint is recognized.
Still further, according to the present invention, similarly to the pixel or the group of pixels, the signals from the surrounding pixels or the group of the pixels are switched around the array by the pixel or the group of the pixels by the selector signal from the totaling means 5. A buffer circuit consisting of a selector for outputting data and a register for holding the output of the selector with a write signal from the counting means and outputting data held in surrounding pixels or a group of pixels is arranged, and a shift operation is performed. Holds the data sent from the pixel or group of pixels.
[0010]
The present invention (claim 2) is formed on the fingerprint memory or the fingerprint recognition means or both in the sensor means 1..
[0013]
The present invention (claim3) Has means for connecting the register to the fingerprint memory 3 and reading and writing data in the fingerprint memory 3 via the register.
The present invention (claim4) In the sensor means 1
An element having a contact surface and converting an unevenness of the contact surface into a capacitance is included.
The present invention (claim5) In the sensor means 1
The light-emitting circuit includes a light-emitting circuit and a light-receiving circuit that receives light from the light-emitting circuit reflected by the skin of the finger.
[0014]
The present invention (claim6) In the sensor means 1
It is composed of two metal surfaces and a buffer filled between the metal surfaces, and converts into a change in capacitance between the metal surfaces based on shrinkage of the buffer due to fingerprint irregularities.
The present invention (claim7) In the sensor means 1
It is composed of two metal surfaces and a buffer filled between the metal surfaces, and the upper metal surface and the lower metal surface come into contact with each other through the cavity of the buffer based on the unevenness of the fingerprint. The two metal surfaces are configured to have the same potential.
[0015]
The present invention (claim8) Connects the sensor means 1 and the fingerprint recognition means 2 by wiring, and the wiring between the sensor means 1 and the fingerprint recognition means 2 is arranged on the substrate of the semiconductor integrated circuit with an interlayer film interposed therebetween. Do
As described above, in the present invention, a plurality of sensor means 1 for detecting the unevenness of a fingerprint are spread over an integrated circuit and used as a fingerprint sensor. Also, the fingerprints collected by this sensor are recognized by the fingerprint recognition means 2 mixedly mounted on the same integrated circuit, and the registered fingerprints are collated with the fingerprints at high speed. This makes it possible to construct a fingerprint recognition system that is much smaller than in the past, and it is possible to incorporate authentication by fingerprint recognition of an IC card or the like.
[0016]
Further, the fingerprint recognition integrated circuit of the present invention is a sensor element for converting unevenness due to a fingerprint of a contacted finger into an electric signal, a sensor circuit for processing the electric signal converted by the sensor element and outputting predetermined data, A fingerprint memory in which fingerprint data indicating unevenness due to a fingerprint is registered in advance, and an arithmetic circuit that outputs a comparison result obtained by inputting the data sent from the sensor circuit and the fingerprint data in the fingerprint memory to an AND element. A fingerprint recognition integrated circuit comprising a plurality of pixel units provided.
According to the present invention, it is possible to perform from fingerprint reading to recognition in a pixel unit portion in one pixel unit.
In the above invention, there is provided a control circuit for summing up the entire collation result output from the arithmetic circuit. This control circuit generates a fingerprint recognition result based on the totalized collation result of each pixel unit.
In the above invention, the plurality of pixel units are arranged in a matrix.
In the case of the invention in which the above pixel units are arranged in a matrix, data from a sensor circuit in the same pixel unit and data from surrounding pixel units are input, and each pixel unit that selects and outputs predetermined data And holding and transferring means provided for each pixel unit for holding the data output from the selecting means and outputting the data to the arithmetic circuit and the selecting means in the surrounding pixel units. The control circuit outputs a select signal for selecting the predetermined data to the selecting means, and outputs a write signal for outputting the data held in the holding and transferring means to the arithmetic circuit and the selecting means in the surrounding pixel unit. I do.
In the above invention, a buffer unit that is arranged around the pixel units arranged in a matrix and holds data output from the outermost pixel unit may be newly provided.
[0019]
In the above inventionIsA buffer unit, to which the data output from the outermost pixel unit and the data output from the surrounding buffer unit are inputted, and to select and output predetermined data; and to output the data output from the selection means. The holding and transfer means for holding and outputting this data to the outermost pixel unit and the surrounding buffer unit.

[0020]
In the above invention, the sensor element includes a contact electrode having a contact surface exposed to the outside, and detects a capacitance generated at the contact electrode. Further, the sensor element includes an upper electrode and a lower electrode opposed to the upper electrode at a predetermined distance from the upper electrode, and detects a change in capacitance between the upper electrode and the lower electrode. A buffer is provided between the upper electrode and the lower electrode. Further, a space is provided between the upper electrode and the lower electrode. Further, the sensor element is arranged on the sensor circuit.
[0021]
BEST MODE FOR CARRYING OUT THE INVENTION
FIG. 2 shows the configuration of the fingerprint recognition integrated circuit of the present invention.
In the configuration shown in the figure, a sensor circuit 102 for collecting a fingerprint is formed on an integrated circuit chip, a recognition circuit 104 for recognizing read data, and a fingerprint memory 103 as a sample of the fingerprint to be recognized are formed on the same chip. Things.
Further, the sensor circuit 102 includes a plurality of sensor circuits each having a size of several μm, and the recognition circuit 104 is a circuit configured by a normal logic circuit for performing recognition.
[0022]
In the fingerprint recognition integrated circuit according to the present embodiment, as shown in FIG. 2A, a plurality of pixels (pixel units) 101 are arranged in a matrix to form a pixel unit array.
The pixel unit 101 includes a sensor element 102a that converts unevenness due to a fingerprint of a contacted finger into an electric signal (not shown) and a sensor unit that processes the electric signal converted by the sensor element 102a and outputs predetermined data. The sensor circuit 102 for detecting the shape of the fingerprint 102b is provided. Further, a fingerprint memory 103 for holding a registered fingerprint of the user is provided, and a recognition circuit 104 for collating the fingerprint data detected by the sensor circuit 102 with the registered fingerprint data is provided. Control of the pixel unit 101 and totalization of recognition results are performed.
[0023]
The registered fingerprint data of the user is divided and stored in the fingerprint memory 103 in each pixel unit 101. The fingerprint shape of the finger placed on the fingerprint recognition integrated circuit in FIG. 2A is converted into an electric signal by the sensor circuit 102 in all the pixel units 101. The recognition circuit 104 performs signal processing using the electric signal (data) related to the fingerprint shape converted by the sensor circuit 102 and the registered fingerprint data in the fingerprint memory 103, and outputs a recognition result.
[0024]
Recognition results from each pixel unit 101 are totaled by the control circuit 111, and based on the totaled result, the control circuit 111 generates a recognition result and outputs it to the outside. The above processing can be performed in a massively parallel manner at the same time, and the parallel processing achieves a reduction in recognition processing time and a reduction in power consumption. Also, in each pixel unit 101, a plurality of sensor units and fingerprint memories are mounted for one recognition circuit, and each sensor circuit and fingerprint memory are switched and used by a control signal from a control circuit, thereby reducing area. Is also possible. Further, the sensor circuit may include a plurality of sensor elements.
[0025]
As shown in FIGS. 2B and 2C, the pixel unit 101 includes an authentication circuit portion such as a fingerprint memory 103 and a recognition circuit 104 and a sensor circuit 102 in a logic circuit layer 130 and a sensor layer 131. That is, by arranging the pixel units over the substrate 140, the degree of integration of the pixel units can be improved.
With the above configuration, the fingerprint recognition system can be configured on an integrated circuit chip, and a very small fingerprint recognition system can be realized. For this reason, the fingerprint recognition system can be incorporated in an arbitrary place such as a small and thin one such as an IC card.
[0026]
Further, since the sensor circuit 102, the recognition circuit 104, and the like are provided on one integrated circuit chip, the data cannot be falsified at the time of data transfer between these devices, so that unauthorized recognition can be prevented.
[0027]
【Example】
[First Embodiment]
This embodiment will be described with reference to FIG.
In FIG. 2A, a set of a recognition circuit 104 or a fingerprint memory 103 for holding fingerprint data is set to one pixel (pixel unit) for each of the sensor circuits in the sensor circuit 102 or every several. Each pixel unit can hold data for one pixel unit or one pixel unit of a plurality of fingerprint images. This fingerprint image becomes registered fingerprint data for the user, and is stored separately in each pixel unit.
[0028]
By transmitting a memory select signal from the aggregation device (control circuit) 111 to the fingerprint memory 103 and switching the data output by the fingerprint memory 103 with the signal, a plurality of data can be distinguished and output.
FIG. 2C illustrates an example in which a recognition circuit 104 is provided in a sensor layer above a logic circuit device provided on a substrate 140, and a sensor circuit 102 is mounted in a sensor layer above the logic circuit device. This is set in the pixel unit.
[0029]
A set of the sensor circuit 102, the recognition circuit 104, and the fingerprint memory 103 is called a pixel (pixel unit), and recognition is performed for each pixel unit or in cooperation with surrounding pixel units. The recognition results are sent to the control circuit, and the total recognition results are totaled.
In this configuration, since the processing before the final aggregation is performed in units of each pixel unit, parallel processing becomes possible, and the overall recognition processing time can be reduced.
Further, by changing the number of pixel units, it is possible to easily change the area of the reading unit or change the reading resolution.
As shown in FIG. 2C, by stacking logic circuits such as the sensor circuit 102 and the recognition circuit 104, the area and power consumption can be reduced.
[0030]
As shown in FIG. 3, the sensor element in the sensor circuit disposed on the sensor layer includes a contact electrode 202 having a contact surface disposed on an interlayer insulating film 201, and a wiring layer 202a connected to the contact electrode 202. , The contact electrode 202 and the wiring layer 202a constitute a part of the sensor circuit. The contact electrode 202 is arranged on the outermost surface of the pixel unit unit, and directly touches a finger to be fingerprint-recognized, and detects a capacitance generated when the finger contacts the finger. The signal detected by the contact electrode 202 is transmitted to the recognition circuit by the wiring layer 202a.
In this sensor element, the capacitance of the contact electrode 202 is measured, and the unevenness of the fingerprint at the portion touched by the contact surface is detected. Since the structure in FIG. 3 is very simple and can be miniaturized, it is possible to improve the resolution of data for a fingerprint to be detected.
[0031]
[Second embodiment]
FIG. 4 shows the configuration of a fingerprint recognition integrated circuit according to a second embodiment of the present invention.
The fingerprint recognition integrated circuit shown in FIG. 1 includes a sensor circuit 102 for detecting the shape of a fingerprint, a fingerprint memory 103 for holding a registered fingerprint, a register 105, and an arithmetic circuit, as each pixel unit 101 that performs from fingerprint collection to fingerprint data collation. (Collation circuit) 106, and a recognition circuit 104 for collating the detected fingerprint data with the registered fingerprint data. The register 105 holds the output of the sensor circuit 102, and the arithmetic circuit 106 collates the output of the register 105 with the output of the fingerprint memory 103.
[0032]
The arithmetic circuit 106 of each pixel unit 101 outputs the result data of the collation to the data bus 112, and the control circuit 111 totalizes the collation results of each pixel unit 101. The control circuit 111 also generates a write signal for the register 105 in the recognition circuit 104. By arranging a plurality of the pixel units 101 in an array and connecting them with the control circuit 111 and the data bus 112, a fingerprint recognition integrated circuit that performs from fingerprint detection to authentication is realized.
[0033]
FIG. 5A shows a circuit configuration of the fingerprint memory 103.
The fingerprint memory 103 can be realized by a simple inverter element. Although the circuit shown in FIG. 1 can hold 1-bit fingerprint data, by increasing the capacity, it is possible to hold fingerprint data for a plurality of fingers or a plurality of people.
FIG. 5 shows the configuration of the arithmetic circuit 106. The arithmetic circuit 106 shown in the figure can be realized by an AND element.
[0034]
In the above description, a sensor element having one contact electrode is used, but the sensor element is not limited to this. For example, as shown in FIG. 6, a light emitting element (light emitting circuit) 602 and a light receiving element (light receiving circuit) 603 are provided on the interlayer insulating film 201, and the light emitting element 602 and the light receiving element 603 are protected by a transparent protective film 604. I have. The light emitting element 602 is supplied with power for light emission by the wiring layer 602a. The light receiving element 603 is connected to a recognition circuit (not shown) disposed below the interlayer insulating film 201 by a wiring layer 603a. This sensor element uses a light emitting element 602 as a light source, and optically detects unevenness of a fingerprint by a light receiving element 603.
[0035]
In the sensor element shown in the figure, the light emitting element 602 emits light, reflects the light on the skin of the finger, and detects the unevenness of the fingerprint on the upper part of the sensor element. Two wiring layers 602a and 603a are formed on the substrate on which the integrated circuit is formed, with the interlayer insulating film 201 interposed therebetween, and the wiring connecting the sensor circuit 111 and the recognition circuit 104 is formed. Controls the light emission of the light emitting element 602 and measures the light receiving intensity of each light receiving element 603. The light emitting element 602 and the light receiving element 603 are covered with a transparent protective film. Light emitted from the light-emitting element 602 passes through the protective film 604, is reflected by a finger, passes through the protective film 604 again, and reaches the light-receiving element 603.
The above configuration does not contact the sensor circuit 111 and does not need to change the shape of the sensor circuit 111 at the time of measurement, so that the highly reliable sensor circuit 102 can be configured.
[0036]
Further, as shown in FIG. 7, a lower electrode 204 may be provided on the interlayer insulating film 201, and an upper electrode 205 may be provided above and separated from the lower electrode 204. Note that a buffer 206 is filled between the upper electrode 205 and the lower electrode 204, and the upper electrode 205 is protected by a protective film 207. When the irregularities of the fingerprint touch the surface of the sensor element (the surface of the protective film 207) in FIG. 7, the buffer 206 contracts in accordance with the shape of the irregularities, the upper electrode 205 bends, and the distance between the upper electrode 205 and the lower electrode 204 decreases. Change. If the gap changes due to the touch of the unevenness of the fingerprint, the capacitance generated on the lower electrode 204 also changes. Therefore, a capacitance change occurring in the lower electrode 204 is detected and measured by a recognition circuit connected to the lower electrode 204 via the wiring layer 204a, so that a fingerprint of a portion touching the sensor circuit including the sensor element is detected. Can be detected.
[0037]
The above configuration is very simple and can be miniaturized, so that the resolution of fingerprint data to be read can be improved.
Further, since the sensor element can be protected by the protective film 207, the sensor element does not come into direct contact with metal or the like, so that deterioration of the sensor element can be prevented.
Further, the protective film 207 may be opaque, and printing on the protective film 207 is also possible.
[0038]
As shown in FIG. 8, in the configuration of the sensor element shown in FIG. 7, the buffer 206 between the lower electrode 204 and the upper electrode 205 is removed, and the space between the lower electrode 204 and the upper electrode 205 is removed. A similar effect can be obtained even if the device 206 is provided. This sensor element has the same configuration as that of the sensor element shown in FIG. 7, but has a flexible buffer 206 so that the two metal surfaces of the lower electrode 204 and the upper electrode 205 are formed on the lower electrode 204 as a space 206a. When the convex portion of the fingerprint touches, the buffer 206 contracts due to the pressure, and the upper electrode 205 to which an appropriate potential is applied comes into contact with the lower electrode 204, and the lower electrode 204, which changes at this time, It detects the unevenness of the fingerprint touching the fingerprint recognition integrated circuit whose potential has been measured.
[0039]
A wiring layer 204a, through which a wiring connecting the sensor circuit 111 and the recognition circuit 104 passes, is formed on the substrate on which the integrated circuit is formed with the interlayer film 201 and the like interposed therebetween, and the recognition circuit 104 Measure the potential.
The above configuration is very simple, and it is possible to improve the resolution of the fingerprint data to be read because it can be miniaturized.
In addition, since the sensor element can be protected by a protective film, the sensor element does not come into direct contact with metal or the like, and thus deterioration of the sensor element can be prevented. Further, the protective film 207 may be opaque, and printing on the protective film 207 is also possible.
[0040]
[Third embodiment]
Next, a third embodiment will be described.
The above-described fingerprint recognition integrated circuit, by placing a finger on a fingerprint recognition area in which pixel units are arranged in a matrix, the fingerprint shape of the finger placed and the data stored in the fingerprint memory for each pixel unit. Compare. For example, as shown in FIG. 9, the fingerprint authentication area does not recognize the entire area where the fingerprint of the finger 901 exists, but recognizes a part of the area where the fingerprint exists. Since the fingerprint recognition integrated circuit becomes large when the entire region where the fingerprint is present is set as the recognition target, the recognition target region is made small as long as the fingerprint authentication is possible. In such a background, since the data stored in the fingerprint memory stores data in a state where the relative positional relationship between the fingerprint recognition area and the finger is predetermined, the position of the finger with respect to the fingerprint recognition area is stored. However, if the position is different from the position based on the data stored in the fingerprint memory, correct fingerprint authentication cannot be performed.
Therefore, as described below, in the third embodiment, the detected fingerprint data is shifted to the upper, lower, left, and right pixel units.
[0041]
In the fingerprint recognition integrated circuit of the present embodiment, each pixel unit 101 of the fingerprint recognition integrated circuit shown in FIG. 2A is replaced with a pixel unit 101a having a configuration shown in FIG. Connected. FIG. 10 shows the configuration of the fingerprint recognition integrated circuit according to the third embodiment of the present invention. In the configuration shown in the figure, a selector 107 is added to the recognition circuit 104 shown in FIG. 4 and the output of the register 105 is passed to the upper, lower, left and right pixel units.
The configuration shown in FIG. 10 is different from that of the first embodiment in that a selector 107 is inserted between the output of the sensor circuit 102 and the input of the register 105, and signals from other pixel units are input to the selector 107. Then, the output of the register 105 is transmitted to the upper, lower, left, and right pixel units.
[0042]
First, the configuration of the pixel unit 101a will be described. In this embodiment, a selector 107 is newly provided. Further, a register (holding and transferring means) 105a for holding a signal (data) output from the sensor circuit 102 and outputting (transmitting) the data to the selectors of the upper, lower, left, and right pixel units is provided. Therefore, the selector 107 of the pixel unit 101a receives the signals from the sensor circuit 102 and the outputs of the registers of the upper, lower, left, and right pixel units. In the present embodiment, the control circuit 111 outputs a select signal to the selector 107 in addition to a write signal to the register 105a.
[0043]
In the pixel unit of FIG. 10 as well, the fingerprint data detected and converted by the sensor circuit 102 is held in the register 105a via the selector 107 in the initial stage (the stage of detecting the fingerprint). In this initial stage, the selector 107 connects the signal from the sensor circuit 102 to the register 105a according to the select signal from the control circuit 111. In this embodiment, when fingerprint data is stored in the register 105a, the control circuit 111 controls the selector 107 with a select signal to select fingerprint data from another pixel unit. Output to the register 105a.
[0044]
Under the control of the control circuit 111, the register 105a holds the fingerprint data detected by the sensor circuit of the pixel unit on the left, for example, different from the initial detection stage. That is, the detected data is shifted to the upper, lower, left, and right pixel units by the select signal from the control circuit 111. Therefore, according to the present embodiment, the fingerprint data detected in the initial stage can be shifted in desired directions, up, down, left and right, under the control of the control circuit 111. This shift makes it possible to correct the difference between the position of the fingerprint data detected by the sensor circuit 102 and the position of the fingerprint data held in the fingerprint memory 103, thereby improving the authentication rate.
[0045]
[Fourth embodiment]
[0046]
Next, a fourth embodiment of the present invention will be described.
In the fingerprint recognition integrated circuit according to the fourth embodiment, a buffer (buffer unit) 141 is added around a pixel unit array including the pixel units 101a arranged in a matrix so as to extend the pixel units. The buffer unit 141 is connected to the pixel unit 101a arranged on the outer periphery of the pixel unit array. By arranging at least the maximum number of stages of the number of shifts around the array (pixel unit array), the buffer unit 141 can hold all data overflowed by the shift operation.
[0047]
The buffer unit 141 will be described. As shown in FIG. 13, the buffer unit 141 includes a selector 141a and a register 141b, and operates with the same signal as the selector signal generated by the control circuit 111 for each pixel unit selector and the write signal to the register. By arranging the buffer unit 101 around the pixel unit array composed of pixel units and connecting the buffer unit 101 vertically and horizontally like the pixel unit, it is possible to hold data that protrudes from the pixel unit array when shifting the detected fingerprint data. Thus, data loss at the time of shifting can be prevented.
[0048]
[Fifth embodiment]
FIG. 14 shows the configuration of the fingerprint recognition integrated circuit according to the fifth embodiment of the present invention. The fingerprint recognition integrated circuit shown in the figure is the one in which the register 105 and the fingerprint memory 103 in the configuration of the second embodiment are connected. This makes it possible to read and write data in the fingerprint memory 103 via the register 105.
In the fingerprint recognition integrated circuit of the fifth embodiment, each pixel unit 101 arranged in a matrix is a pixel unit 101b in which a fingerprint memory 103 and a register 105 are connected as shown in FIG. As described above, the registered fingerprint data of the user to be authenticated is stored in the fingerprint memory 103 in advance, but by connecting to the register 105, the fingerprint data newly captured by the sensor circuit 102 can be stored. It can be easily stored as newly registered fingerprint data.
[0049]
[Sixth embodiment]
The connection between the fingerprint memory and the register according to the fifth embodiment can be applied to the fingerprint recognition integrated circuit shown in FIG. 10, and as shown in FIG. 15, the pixel unit 101c having the fingerprint memory 103 and the register 105a connected to each other. do it. Then, in the fingerprint recognition integrated circuit including the pixel unit 101c shown in FIG. 15 having the selector 107, if the data write line from the control circuit 111 is connected to one pixel unit in the pixel unit array, the control circuit 111 The registered fingerprint data can be stored in the fingerprint memory. If the data write line from the control circuit 111 is connected to one pixel unit, the pixel unit in FIG. 15 can be shifted. Therefore, it is necessary to sequentially write new registered fingerprint data to all the pixel units using this shift operation. Becomes possible.
It should be noted that the present invention is not limited to the above-described embodiment, but can be variously modified and applied within the scope of the claims.
[0050]
【The invention's effect】
As described above, according to the present invention, a fingerprint recognition system is formed on an integrated circuit by forming a sensor circuit for collecting a fingerprint on the integrated circuit and forming a recognition circuit and a fingerprint memory on the same integrated circuit. A very small fingerprint recognition system can be realized.
[0051]
Also, a pixel (pixel unit) having a matching circuit for holding the registered fingerprint data of the user, detecting the fingerprint data, and comparing the held registered fingerprint data of the user with the detected data, or a group of the pixels (pixel unit) The use of an array made up of fingerprint data makes it possible to perform fingerprint data detection to authentication in parallel and at high speed.
In addition, miniaturization is possible with a simple configuration by forming a wiring layer that sandwiches an interlayer film etc. on the substrate of the integrated circuit and sandwiches the sensor circuit and the recognition circuit, and the recognition circuit measures the capacitance of the sensor circuit. It is possible to improve the resolution of the fingerprint data.
[0052]
Furthermore, it is necessary to change the shape of the sensor circuit so that the finger does not directly contact the sensor circuit by emitting light from the light emitting circuit and detecting the unevenness of the fingerprint by the light receiving intensity of the light receiving circuit with respect to the reflection of the finger. And a highly reliable sensor circuit can be configured.
In addition, the two metal surfaces of the metal pad and the upper layer metal are sandwiched between the sensor circuit by the buffer, and when the finger touches, the distance between the metals changes due to the contraction of the buffer, and the fingerprint of the finger contact portion is changed. Since it is possible to detect irregularities and miniaturize it, it is possible to improve the resolution of fingerprint data, and by protecting it with a protective film, it is possible to prevent the finger from directly touching metal etc. Circuit deterioration can be prevented.
[0053]
Further, the sensor circuit is sandwiched by the buffer 206 so as to form a cavity between the two metal surfaces of the metal pad and the upper layer metal, so that a change in potential due to contraction of the buffer 206 at the time of contact with a finger can be reduced. By performing the measurement, it is possible to detect the unevenness of the fingerprint at the contact portion of the finger, to make the fingerprint finer, and to improve the resolution of the fingerprint data.
Furthermore, by using a set of the sensor circuit, the recognition circuit, and the fingerprint memory as one pixel (pixel unit), parallel processing becomes possible, and the overall recognition processing time can be reduced. By changing the number, it is easy to change the area of the sensor circuit and the resolution.
[0054]
According to the present invention, a sensor element that converts unevenness due to a fingerprint of a contacted finger into an electrical signal, a sensor circuit that processes the electrical signal converted by the sensor element and outputs predetermined data, and a fingerprint that indicates unevenness due to a fingerprint in advance A fingerprint memory in which data is registered, and a plurality of pixel units including an arithmetic circuit for comparing data sent from the sensor circuit with fingerprint data in the fingerprint memory and outputting a result of the comparison are provided.
As a result of this configuration, according to the present invention, it is possible to perform from fingerprint reading to recognition in a pixel unit portion in one pixel unit. Therefore, by forming a plurality of pixel units on the same semiconductor integrated circuit, a system for fingerprint recognition can be configured on one semiconductor chip. As a result, according to the present invention, there is an excellent effect that the system for fingerprint recognition can be mounted at low cost on a small device such as an IC card or a portable device.
[Brief description of the drawings]
FIG. 1 is a principle configuration diagram of the present invention.
FIG. 2 is a configuration diagram of a fingerprint recognition integrated circuit of the present invention.
FIG. 3 is a sectional view schematically showing a configuration of a sensor element according to the present invention.
FIG. 4 is a configuration diagram illustrating a configuration of a pixel unit according to the present invention.
FIG. 5 is a configuration diagram showing a partial configuration of a pixel unit according to the present invention.
FIG. 6 is a sectional view schematically showing another configuration of the sensor element according to the present invention.
FIG. 7 is a sectional view schematically showing another configuration of the sensor element according to the present invention.
FIG. 8 is a sectional view schematically showing another configuration of the sensor element according to the present invention.
FIG. 9 is an explanatory diagram showing a relationship between the fingerprint recognition device of the present invention and a finger.
FIG. 10 is a configuration diagram of a pixel unit configuring a fingerprint recognition integrated circuit according to another embodiment of the present invention.
FIG. 11 is a configuration diagram illustrating an arrangement configuration of a pixel unit according to another embodiment of the present invention.
FIG. 12 is a configuration diagram showing an arrangement configuration of a pixel unit according to another embodiment of the present invention.
FIG. 13 is a configuration diagram illustrating a configuration of a buffer unit.
FIG. 14 is a configuration diagram of a pixel unit configuring a fingerprint recognition integrated circuit according to another embodiment of the present invention.
FIG. 15 is a configuration diagram of a pixel unit configuring a fingerprint recognition integrated circuit according to another embodiment of the present invention.
FIG. 16 is a configuration diagram of a conventional fingerprint identification system.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Sensor means, 2 ... Fingerprint recognition means, 3 ... Fingerprint memory, 4 ... Data bus, 5 ... Aggregating means, 101 ... Pixel (pixel unit), 102 ... Sensor circuit, 102a ... Sensor element, 102b ... Sensor section, 103 ... Fingerprint memory, 104 ... Recognition circuit, 105 ... Register, 106 ... Operation circuit (collation circuit), 111 ... Control circuit (totaling device), 112 ... Data bus, 130 ... Logic circuit layer, 131 ... Sensor layer, 140 ... Substrate , 201 ... interlayer insulating film, 202a ... wiring layer, 202 ... contact electrode, 204 ... lower electrode, 205 ... upper electrode, 206 ... buffer, 206a ... space, 207 ... protective film, 602 ... light emitting element, 602a, 603a ... Wiring layer, 603: light receiving element, 604: protective film.

Claims (15)

Sensor means for laying out a plurality of pixels having a sensor circuit for converting unevenness due to a fingerprint into an electric signal in an array, and detecting a fingerprint of the finger as an electric signal by contacting the finger,
A fingerprint memory for registering fingerprint data in advance for each pixel or for each group of pixels,
The pixel or each, provided we are in each group of the pixel, a fingerprint recognition means for outputting the collation result,
A data bus for transferring the collation result sent by the fingerprint recognition means,
A counting means connected to the data bus, for counting the collation results sent to the data bus, and sending a write signal to the fingerprint recognition means;
A selector that switches and outputs a signal from a surrounding pixel or a group of the pixels and the output of the sensor unit by a select signal from the counting unit, and holds an output of the selector by a write signal from the counting unit. A register for outputting data held in a peripheral pixel or a group of the pixels, and a collation result obtained by inputting an output of the register and an output of the fingerprint memory to an AND element. The pixel or the group of pixels provided with the fingerprint recognition means to be sent to a data bus shifts the data held in an array around,
The tallying unit tally the collation result of the whole pixel or the total of the comparison results sent for each group of the pixel ,
A second signal for switching signals from surrounding pixels or groups of pixels around the array of pixels or groups of pixels in the same manner as the pixels or groups of pixels by using a selector signal from the counting means. Selector and
A buffer circuit comprising a register for holding the output of the selector with a write signal from the counting means and outputting data held in surrounding pixels or a group of pixels is arranged, and shifting the pixel or the pixel by a shift operation. A fingerprint recognition integrated circuit for holding data sent from a group . The sensor means comprises:
2. The fingerprint recognition integrated circuit according to claim 1, wherein said fingerprint recognition integrated circuit is formed on said fingerprint memory, said fingerprint recognition means, or both. Connecting the said fingerprint memory and said register, fingerprint recognition integrated circuit according to claim 1, further comprising means for reading and writing data of said fingerprint memory through the register. The sensor means comprises:
3. The fingerprint recognition integrated circuit according to claim 1, further comprising an element having a contact surface and converting an unevenness of the contact surface into a capacitance. The sensor means comprises:
3. The fingerprint recognition integrated circuit according to claim 1, further comprising a light-emitting circuit and a light-receiving circuit for receiving light from the light-emitting circuit reflected by the skin of a finger. The sensor means comprises:
3. A method according to claim 1, wherein the first and second metal surfaces are configured to include a buffer filled between the metal surfaces, and the capacitance is converted into a capacitance change between the metal surfaces based on shrinkage of the buffer due to unevenness of a fingerprint. 3. The fingerprint recognition integrated circuit according to item 2. The sensor means comprises:
An upper metal surface and a lower metal surface are made of two metal surfaces and a buffer filled between the metal surfaces, and the upper metal surface and the lower metal surface are in contact with each other through a hollow portion of the buffer based on unevenness of the fingerprint. 3. The fingerprint recognition integrated circuit according to claim 1, wherein the two metal surfaces are configured to have the same potential. And connect the wiring and the fingerprint recognition means and said sensor means, claims and said sensor means, the wiring between the fingerprint recognition means is arranged to sandwich an interlayer film on a substrate of semi-conductor integrated circuit 1 3. The fingerprint recognition integrated circuit according to claim 2. A sensor element for converting unevenness due to the fingerprint of the contacted finger into an electric signal,
A sensor circuit for processing the electrical signal converted by the sensor element and outputting predetermined data;
A fingerprint memory in which fingerprint data indicating unevenness due to fingerprints is registered in advance,
A plurality of pixel units arranged in a matrix , comprising: an arithmetic circuit that outputs a matching result obtained by inputting data sent from the sensor circuit and fingerprint data of the fingerprint memory to an AND element;
And a control circuit that aggregates the collation results output from the arithmetic circuit and generates a fingerprint recognition result based on the entire collation result of each of the aggregated pixel units ,
For each of the pixel units,
Selecting means for receiving data from a sensor circuit in the same pixel unit and data from surrounding pixel units, selecting and outputting predetermined data,
Holding and transferring means for holding the data output from the selecting means and outputting the data to the arithmetic circuit and the selecting means in the surrounding pixel unit;
With
The control circuit outputs a select signal for causing the selecting means to select the predetermined data, and a write signal for outputting data held in the holding and transferring means to the arithmetic circuit and a selecting means in a surrounding pixel unit. And output
A fingerprint recognition integrated circuit, comprising: a buffer unit arranged around the pixel units arranged in a matrix and holding data output from an outermost pixel unit . The fingerprint recognition integrated circuit according to claim 9 ,
The buffer unit includes:
A selection unit to which data output from the outermost pixel unit and data output from the surrounding buffer units are input, and select and output predetermined data;
A fingerprint recognition integrated circuit, comprising: holding and transferring means for holding the data output from the selecting means and outputting the data to the outermost pixel unit and the surrounding buffer unit. The fingerprint recognition integrated circuit according to any one of claims 9 and 10 ,
The fingerprint recognition integrated circuit, wherein the sensor element includes a contact electrode having a contact surface exposed to the outside, and detects a capacitance generated at the contact electrode. The fingerprint recognition integrated circuit according to any one of claims 9 to 11 ,
The sensor element includes an upper electrode and a lower electrode which is opposed to the upper electrode at a predetermined distance from the upper electrode, and detects a change in capacitance between the upper electrode and the lower electrode. Integrated circuit. The fingerprint recognition integrated circuit according to claim 12 ,
A fingerprint recognition integrated circuit, wherein a buffer is disposed between the upper electrode and the lower electrode. The fingerprint recognition integrated circuit according to claim 12 ,
A fingerprint recognition integrated circuit, wherein a space is provided between the upper electrode and the lower electrode. The fingerprint recognition integrated circuit according to any one of claims 9 to 14 ,
The fingerprint recognition integrated circuit, wherein the sensor element is disposed on the sensor circuit.

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