DE19929671A1 - Finger-print detection method e.g. for credit cards and cash dispensers - Google Patents

Abstract

A method for recognising an image as a finger print, in which the image of a suspected print is detected and the detected image is subjected to a two-dimensional Fourier transformation, and the modulus of the transformed values are integrated within a given frequency band (v3-v2) with regard to its position and width. The value of this integral is then treated as a measure for the likelihood that it is an image of a finger print. The position and width of the frequency band are selected within an upper limit (v4) and a lower limit (v1).

Description

The invention relates to a method for recognition of an image as a fingerprint.

In addition to the long-standing meaning of the fingers Imprint identification in criminology attains the ideals Machine-based fingerprinting too increasing importance in other areas, e.g. Credit card and cash dispenser and at Zu access control to buildings or authorization control for computer systems, telecommunication devices, etc.

In contrast to recording and checking other people related features such. B. the structure of the iris, the length and shape of fingers, voice or facial features, offer fingerprints than with simple, quick through feasible and not uncomfortable procedures for a person detectable. An overview of personal characteristics is the article "It had to be you" in IEEE Spectrum, February 1994. Add to that fingerprints and their structures are well researched. Careful screening and Statistics have shown that each person's fingerprints People individually and even with identical twins different, albeit similar.

The pattern of the fingerprints is from the papillary lines, also called "ridges", being used for identification features of importance, especially referred to as minutiae are, namely endpoints, branches, islands and others singular characteristics. Basic terms are just like criminal tical methods in the standard work "The Science of Finger prints ", United States Department of Justice, FBI, U.S. Government Printing Office, Rev. 12-84, Catalog No. JI. 14/2. F49 / 12/977 included. More details on automa  Classification of fingerprints are an example to be found in "PCASYS-A Pattern-Level Classification Automatic System for Fingerprints ", G.T. Candela et al., U.S. Department of Commerce, August 1995.

To make it easier to read and to make repetitions too some specific subject areas will be avoided below press explains or defines.

Fingerprint:
The raw image of a fingerprint in machinable form.

Identity:
A reference to a specific person.

Identity of a fingerprint:
The connection of a fingerprint with an identity. In addition, the assurance that a fingerprint originates from a specific finger of the person.

Encoded fingerprint: The amount of extra here and for the recognition rele vanten characteristics (minutia types, -coordina orientations,. . .).

Inquiry fingerprint:
A fingerprint whose identity is to be ascertained or checked.

Reference:
The information obtained from a non-empty set of fingerprints of known identity, which serves as the basis for the comparison with the request fingerprints.

Archive:
A lot of references of different identities.

Match function:
A Boolean function that provides an assurance for each pair of a fingerprint and a reference whether the fingerprint has the same identity as the reference or not (the path to identity always leads through the identity of the fingerprint.).

ID:
A method of determining the identity of a fingerprint request from the references of an archive using a match function.

Enrollment:
A method by which a reference is generated from a set of fingerprints of known identity.

Enrollment rate:
The amount of fingerprints accepted by the enrollment to create a reference.

Especially in the "non-criminal" applications at the beginning the so-called "enrollment", that is the registration or the inclusion of fingerprints in an archive of Reference images. The recording is usually done with the help of print sensors, e.g. B. on optical or capacitive Base work. A picture of bad reference pictures in the archive naturally the later lei deteriorates ability of the fingerprint system and should therefore ver be avoided. There can be different causes lead to poorer quality of the reference images, e.g. B. damp Skin, different positions of the finger, too high or low contact pressure, smearing, etc. Usually the new recording of fingerprints is done by a person monitors and fingerprints that have certain minimums l Quality requirements will not be met immediately eliminated.

The tacit assumption that one is from a fingerprint sensor-supplied image actually from a finger comes from, d. H. represents a fingerprint may not ge be hit. Rather, it must be considered that the image comes from other structures that the sensor he  borders, for example a textile surface, an animal skin Bath sponge, etc.

An object of the invention is to be as simple as possible to specify the procedure with the help of which it is quickly recognized can be whether an image, e.g. B. one with the help of a finger print-sensor captured image, a fingerprint at all is.

By quickly eliminating invalid images for example enrollment, the formation of an enrollment Sentence or identification accelerated and more secure become.

The task is accomplished with a procedure of the beginning mentioned type, in which according to the invention the picture of a suspected impression is captured, the captured image subjected to a two-dimensional Fourier transformation will, the values of the power of the transform within one predetermined in terms of its location and width th frequency band ν3-ν2 are integrated, and the value this integral is used as a measure of the probability is that these are pictures that obviously have no fingers are prints.

The invention offers the possibility of images that are obvious Lich fingerprints are from another, time-consuming Exclude processing, so that on the one hand a time savings and on the other hand also an abuse, e.g. B. through an intended enrollment of a fabric sample and later use of the fabric pattern can be prevented.

An improved evaluation can result if location and Width of the frequency band within an upper bound ν4 and a lower bound ν1 can be chosen, the numerical values of these bounds by the characteristics  line structures of a representative set of fin can be determined.

In order to eliminate interference originating from the line / column structure of a fingerprint sensor, it can be advantageous if frequency ranges are excluded from the integration which are in a band of width ν _x around the y-axis and in a band of width ν _y around the x- Axis of the transform lie, where ν _x and ν _{y are} constants that are determined empirically as characteristics of a sensor used in the acquisition of the image.

A favorable further development of the method is characterized in that a cutoff method according to the regulation is used to free the integrand from its direct component

fs (ν, ϕ) = fs (ν, ϕ) - FS _min for (FS (ν, ϕ) - FS _min ) ≧ 0 and
fs (ν, ϕ) = 0 for (FS (ν, ϕ) - FS _min ) <0

is carried out in which FS _{min is} constant and is determined empirically from the characteristics of a sensor used in the acquisition of the image. The removal of the mostly disruptive DC component takes place effectively and with little effort in this way.

A further increase in security or an acceleration the search can result if between top and bottom barrier ν4, ν1 after a maximum of the integral over the frequency band ν3-ν2 is searched, the condition ν1 <ν2 <ν3 <ν4 is observed, whereby after finding one Maximum whose value compared with a predetermined value and overwriting this value as a criterion for the Presence of a fingerprint is taken.

It has proven to be efficient in practice if the width of the band is between 0.1 mm ^-1 and 0.3 mm ^-1 .

On the other hand, the search for a maximum can be omitted if ν3 = ν4 and ν1 = ν2 are set, for example ν3 = ν4 between 3 and 4 mm ^-1 and ν1 = ν2 between 1 and 2 mm ^-1 .

A sometimes very useful, accuracy-enhancing, additional evaluation criterion results from the fact that of a histogram is created for the captured image, which Indicates the number of pixels above the gray values, and a lower one Limit (FP-Min) of the histogram and an upper limit (FP-Max) of the histogram is recorded, in which limit values the number of pixels has dropped below a specified minimum, and it is checked whether the two limit values specify a Function FS-Max = F (FP-Min) within fixed toles border limits.

The invention together with further advantages is described below With reference to the drawing explained in more detail demonstrate

Fig. 1 an exemplary image of a fingerprint,

Fig. 2 shows the theoretical image of a transform in the frequency range;,

Fig. 3, the image of the Fourier transform of a fingerprint of Fig. 1,

Fig. 4a and 4b, the variation of the magnitude of the Fourier Transform along a brief break in two lines through the origin in Fig. 3 is measured,

Fig. 5 is a curve similar to Fig. 4a and 4b after filtering by a bandpass, and

Fig. 6a and 6b histograms of geliefer from a sensor th gray values.

The starting point for the method according to the invention is an image that is generated, for example, with the aid of a fingerprint sensor. In experiments by the inventors, bitmaps with 256 × 256 pixels and 256 gray values were used, and FIG. 1 shows an example of a fingerprint image or finger prints.

The image now becomes a two-dimensional Fourier transform subjected to the frequency spectrum in polar representation won as amount and phase share and the phase share discarded. The nature of the method used causes the parts with low fre collect sequences in the "corners". For the following analysis the origin is transformed so that DC and low-frequency components are close to the origin. Symme effect and periodicity of the Fourier transform, that this operation can also be called the permutation of the quadrants able to see. Such transformation methods are known, and in this regard, reference is made, for example, to: "The Scientist's and Engineer's Guide to Digital Signal Proces sing ", S. W. Smith, 1999, California Technical Publishing, ISBN 0-9660-176-7-6, Chapter 24. "Linear Image Processing" (p. 397-421).

With reference to FIG. 2, the following parameters and functions above the parameters are introduced for the evaluation of the frequency spectrum (FS (ν, ϕ)): ((ν, ϕ) is only introduced to formulate the integral simply via a ring can, ϕ has nothing to do with the "phase").

Returning to the example of a fingerprint according to FIG. 1, reference is now made to FIG. 3, where the 2-D Fourier transform of the image according to FIG. 1 is shown. As already indicated above, FIG. 3 shows the magnitude spectrum in shifted form, ie the original quadrants are exchanged so that the DC component is now in the center. It is also noticeable that the Fourier spectrum is symmetrical, so that one can restrict oneself to the analysis of the half image.

If one moves in the image of the transformed in the first and second quadrants along a straight line through the origin, for example the diagonal, and plots the absolute values as a function, curve profiles result as in FIGS. 4a and 4b. Despite the strong fluctuations, a characteristic maximum can be seen that corresponds to the tropical Ride width and can be rated as typical for fingerprint images. The curves thus obtained contain strong fluctuations and, as experience has shown, can show a very different course for each fingerprint, which means that the information content is relatively modest.

The evaluation of this family of curves is replaced by the integral via a quality function G (ν2),

where the function fs (ν, ϕ), which is the result of a cutoff value FS _min from FS (ν, ϕ) according to the regulation

fs (ν, ϕ) = fs (ν, ϕ) - FS _min for (Fs (ν, ϕ) - Fs _min ) ≧ 0 and fs (ν, ϕ) = 0 for (FS (ν, ϕ) - FS _min ) <0 arises.

For the specific value (ν3-ν2) = 0.3 mm ^-1 , curves for the fingerprint of FIG. 1 then result in the form of FIG. 5. For the evaluation of a fingerprint, the maximum of the quality function for fixed parameters ν1, ( ν3-ν2), ν4, FS _{min determined} within the permitted range. These parameters are determined empirically using a reference set of representative fingerprints.

The invention accordingly integrates the amount of the Fourier transform within a frequency band (ν3-ν2) which is predetermined with regard to its position and width, for which purpose reference is made to the underlying circular ring in FIG. 2. The value of the above-mentioned integral as a quality function is used as a measure of the probability that the examined image is actually a fingerprint. When recording fingerprints, e.g. B. for an enrollment, you can specify a limit for the quality function, which allows a concrete decision whether an image is accepted or rejected.

The frequency band is expediently accommodated within an upper bound ν4 and a lower bound ν1; (See the corresponding circles in FIG. 2), the numerical values of these barriers being determined empirically by characteristic line structures of a representative set of fingerprints.

With regard to the aforementioned row / column structure of fingerprint sensors, frequency ranges can be excluded from the integration, which lie in a band of width ν _x around the y-axis and in a band of width ν _y around the x-axis of the transform, as shown in Fig. 2. The values for ν _x and ν _y are determined empirically from the characteristics of the sensor.

One can also search within the bounds ν1 and ν4 for a maximum of the integral over the frequency band (ν3-ν2), whereby practical values for the frequency band kept constant, e.g. B. between 0.1 mm ^-1 and 0.3 mm ^-1 , move.

The search for a maximum can also be omitted if you set ν1 = ν2. Typical values of ν3 = ν4, which are only to be understood as examples, lie between 3 and 4 mml and those of ν1 = ν2 between 1 and 2 mm ^-1 .

An additional criterion that can be used in the evaluation of an image originating from a fingerprint sensor is explained below with reference to FIGS. 6a and 6b. In the diagram of Fig. 6a and 6b, the number of pixels is plotted in the image of the gray values. The example assumes a capacitive sensor and 256 gray values. FIG. 6a is a histogram of the image showing a sensor; that does not represent a fingerprint, but exhausts all limit values available on the part of the sensor, whereby a smallest gray value L is practically determined by the contact of the sensor surface with air and a largest gray value W by the contact of the sensor surface with water. (The gray value 0 corresponds to "black", the gray value 255 corresponds to "white".)

A typical histogram for an actual fingerprint is shown in Fig. 6b, showing that the FP-Min and FP-Max limits are well defined by a steep rise and a steep fall. This histogram can be created from a given image and the upper or lower limit value FP-Max or FP-Min can be determined, the limit values being determined in that the number of pixels there has dropped below a defined minimum. Then one checks whether the two limit values correspond to a predetermined, empirically determined function within fixed tolerance limits. In particular, the function can be a linear function, FP-Max = C * FC-Min, the rise C of this function being used as an evaluation criterion for the question of whether an image represents a fingerprint.

Claims (9)

1. A method for recognizing an image as a fingerprint, characterized in that the image of a suspected imprint is detected, the captured image is subjected to a two-dimensional Fourier transformation, the amount of the transforms integrated within a frequency band ν3-ν2 predetermined in terms of its position and width and the value of this integral is used as a measure of the likelihood that the image is a fingerprint. 2. The method according to claim 1, characterized in that the position and width of the Frequency band within an upper bound ν4 and one lower bound ν1 can be selected, the numerical Values of these barriers through the characteristic lines structures a representative set of fingerprints be determined. 3. The method according to claim 1 or 2, characterized in that frequency ranges are excluded from the integration, which lie in a band of width ν _x around the y-axis and in a band of width ν _y around the x-axis of the transform, where ν _x and νy are constants that are determined empirically as characteristics of a sensor used in the acquisition of the image. 4. The method according to any one of claims 1 to 3, characterized in that a cutoff method according to the regulation to free the integral from its DC component
fs (ν, ϕ) = fs (v, ϕ) - FS _min for (FS (ν, ϕ) - FS _min ) ≧ 0 and
fs (ν, ϕ) = 0 for (FS (ν, ϕ) - FS _min ) <0
is carried out in which FS _{min is} constant and is determined empirically from the characteristics of a sensor used in the acquisition of the image. 5. The method according to any one of claims 2 to 4, characterized in that between the upper and lower bound ν4, ν1 after a maximum of the integral is searched over the frequency band ν3-ν2, the Bedin gung ν1 <ν2 <ν3 <ν4 is observed, after being found a maximum whose value ver with a predetermined value and overwriting this value as a criterion for the presence of a fingerprint is taken. 6. The method according to any one of claims 1 to 5, characterized in that the width of the band is between 0.1 mm ^-1 and 0.3 mm ^-1 . 7. The method according to any one of claims 1 to 6, characterized in that the frequency limits are set with ν3 = ν4, and ν1 = ν2, for example ν3 = ν4 between 3 and 4 mm ^-1 and ν1 = ν2 between 1 and 2 mm ^{-1 is} selected. 8. Procedure for the separation of prints, which before Method according to one of claims 1 to 7 is applied, characterized, that a histogram is created from the captured image, wel ches indicates the number of pixels above the gray values, and a lower limit (FP-Min) of the histogram and an upper one Limit (FP-Max) of the histogram is recorded, in which Limits the number of pixels below a specified minimum has dropped, and it is checked whether the two limit values a given function FS-Max = F (FP-Min) within set tolerance limits. 9. The method according to claim 8,  characterized in that the function a li neare function, and the increase in function as an evaluator tion criterion is used.