FR2915008A1 - Body zone`s e.g. finger, living character determining method for identifying person, involves determining living or non living character of body zone based on difference between ratio of luminance and ratio predicted by reflectance model - Google Patents

Abstract

The method involves illuminating a body zone (6) using light beams emitted between two wavelengths at different spectral components. Luminance reflected by the zone is measured in each of the zones by a camera type luminance detection device (3). The reflected luminance is analyzed based on the wavelengths by comparing the luminance measured for each illuminated zone. The luminance ratio is formed, and a living or non living character of the body zone is determined based on the difference between the ratio of the luminance and a ratio predicted by a reflectance model. An independent claim is also included for a biometric capture optical device for implementing a method for determining a living character of a body zone, comprising a camera type luminance detecting device.

Description

METHOD OF DETECTING THE LIVING CHARACTER OF A BODY AREA AND

  OPTICAL DEVICE FOR IMPLEMENTING THIS METHOD The technical field of the invention relates to the recognition of a biometric characteristic for identifying a person and more precisely the determination and detection of the living character of the wearer of this characteristic.

  Commonly, in order to limit certain operations or steps to authorized persons (for example access in reserved physical or logical places), it is customary to require a biometric characteristic of a person such as the fingerprint or the face using an optical sensor. The luminance information is generally sufficient to collect the biometric characteristic considered, for example, the image of a fingerprint consisting of a number of more or less dark lines separated by more or less clear lines with dots. stopping and modification points of curvature or bifurcation of the lines which constitute the characteristic points of the fingerprint.

  Once the fingerprint is obtained by the sensor, it is transmitted to an image processing unit which compares the recorded image with an image database so as to check whether the image of the recorded fingerprint belongs to the image processing unit. to this database. The recognition of the fingerprint recorded by the processing unit then leads to the authorization of access to certain reserved places, for example by triggering the opening of a door.

  Similarly, there is also known a method of recognizing a two-dimensional face whose image is normalized thanks to the position of the two eyes. Then, a group of operators is passed on the image for processing. Then, the responses of the operators are compared by a processing unit to the responses recorded in a database. The recognition of the image finally leads to the authorization of access.

  Although biometric recognition methods are well known and reliable methods of identifying a person, malicious people may be tempted to imitate or reproduce a person's biometric characteristic, for example by using a photo, a fake finger, even a cut finger on a person (dead finger).

  Several methods have been proposed in the prior art to try to determine the living character of the carrier of a biometric characteristic.

  A first method, especially as described in US 5,719,950, consists in measuring biometric parameters, for example the level of oxygen in the blood or the temperature of the skin. It is also known from US 5,737,439 to use an optical measuring device for detecting blood flow from two different wavelengths.

  A second method, especially as described in document FR 2 849 246, consists of making electrical measurements, for example the measurement of the impedance of the finger.

  However, because of the ingenuity of counterfeiters, it is still necessary to provide new methods for detecting the living character of the wearer of a biometric feature.

  It is thus known to discriminate the real fingers (live fingers) of the fake fingers or dead fingers by performing a succession of images of the illuminated finger 30 with different colors, and as described in particular in the document US 7 147 153. However, this technique is limited by the time required for the acquisitions (the wearer of the fingerprint not having to wait more than a few seconds, preferably more than one second, before the recognition of his fingerprint) and does not apply not for moving fingers in the case of optical biometric capture devices without contact of the finger on the optical device and, more generally, in the case where the capture of the biometry is done without contact and therefore with at least a little movement (case of the face for example).

  It would therefore be particularly advantageous to carry out a method for determining the living character of the wearer of a biometric characteristic such as a fingerprint or a face that does not require relatively long acquisition times (that is to say greater than a handful of seconds) and applying for biometric capture optical devices with or without finger contact on the optical device.

  In order to propose a solution to this problem, according to a first of its aspects, the present invention relates to a method for determining the living character of a body zone, characterized in that it consists in illuminating the body area using at least two light beams respectively emitted at different spectral components between two limiting wavelengths XI and and arranged in such a way that each beam illuminates a different part of the body area; measuring the luminance reflected by the body area in each of the areas illuminated by the two beams; analyzing the reflected luminances as a function of the wavelengths used by comparing, among themselves, the reflected luminances measured for each illuminated area; setting the reflected luminances measured in each illuminated area as ratios; and to conclude whether or not the body area is alive according to the difference between the measured reflected luminance ratios and the ratios predicted by a reflectance model in the case of a living body area.

  In order simultaneously to make it possible to determine the living character of a body area as well as the capture of the biometric characteristic considered, the intensity of each beam is adjusted in such a way that the luminance reflected by the body area of the wearer is substantially constant. between the regions illuminated by the different beams and also in such a way that the luminance reflected by the region of the body area of the wearer illuminated by the beam is substantially identical to the luminances reflected by the regions illuminated by the other beams.

  According to an advantageous embodiment, the method according to the invention comprises a step of emitting the different beams from a source in front of which is placed a device capable of projecting several beams of different spectral components. Optimally, the limiting wavelengths λ 1 and λ 2 determine a wavelength band of between 350 nm and 1 μm.

  Advantageously, by means of the method according to the invention, the luminance reflected by the body area is detected by means of a camera-type luminance detection device.

  According to one embodiment, the method according to the invention comprises the step of placing the body zone presenting the fingerprint at a distance 25 without contact of a biometric capture optical device.

  According to a second of its aspects, the present invention relates to a biometric capture optical device for implementing the method as previously described, characterized in that it comprises a device of luminance detection of the camera type and at least a light source making it possible to project at least two light beams of different spectral components. The present invention is now described with the aid of a purely illustrative and in no way limiting example of the scope of the present invention, and from the illustrations herein. -jointes in which: Figure 1 is a schematic representation of a biometric capture optical device for carrying out the method according to the invention; FIG. 2 is a graph symbolizing the reflectance of the skin as a function of the wavelength for a finger of a carrier between two limiting wavelengths X1 and X2; FIG. 3 is a graph representing the intensity emitted by at least one light source as a function of the wavelength between two limit wavelengths XI and 2 ^ 2; FIG. 4 is a graph showing the luminance reflected by the wearer of the fingerprint between the two limiting wavelengths X1 and 22 in the case where the wearer of the fingerprint is alive and during an implementation. particular of the process according to the invention; FIG. 5 is a graph showing the luminance reflected by the wearer of the fingerprint between the two limiting wavelengths and X2 in the case where the wearer of the fingerprint is not alive and when a fingerprint is particular embodiment of the process according to the invention.

  The present invention applies more particularly for determining the living character of a body area such as a finger, it being understood that the principle according to the invention also applies to any area of the human body that can be acquired and having biometric characteristics that are distinct and unique to each human being. Thus, the principle according to the invention also applies to palm areas, but also to any facial area, for example the entire face, or the ear.

  FIG. 1 is a schematic representation of an embodiment of an optical biometric capture device 1 for carrying out the method according to the invention.

  The optical device 1 comprises a block 2 in which is housed at least one luminance detection device 3 of the camera type and at least two light sources 4, 5 of different spectral components.

  According to another embodiment not shown in Figure 1, the different light beams are emitted by a single light source in front of which is placed a device for projecting a pattern. The target may be for example composed of colored bands.

  Preferably, the detection device 3 is directed towards the body area 6 with a biometric characteristic of the wearer, namely either towards the place where the wearer must affix his body area (preferentially his finger) in the case of an optical device 1 requiring contact between the body area and the optical device 1 on a transparent plate 7, either towards the place where the wearer must place or scroll the body area 6 in the case where the optical device 1 would not require contact direct with the optical device 1 but would allow detection of the body area with biometric feature 6 remotely.

  According to the invention, it is proposed to illuminate the body area, the living character of which is to be determined, with the aid of at least two light beams emitted respectively to different spectral components between two limiting wavelengths. XI and X2, the light beams being arranged in such a way that each beam illuminates a different part of the body area 6.

  Thus, preferably, the regions illuminated by each beam are distinct and cover the entire surface of the body area.

  The luminance reflected by the body area 6 is then measured in the areas illuminated by each light beam.

  The reflected luminances are then analyzed as a function of the wavelengths used by comparing, among themselves, the reflected luminances measured for each illuminated zone.

  The ratio or ratio of the luminances measured for illumination around 760 nm on the luminance measured for illumination around 860 nm is between 1 and 1.2 for a living finger is then put in the form of ratios. A similar ratio can be obtained with other wavelength pairs (typically 633 and 950 nm, or 560 and 580 nm, 500 and 600 nm, 420 and 500 nm). In practice, it is used several lights and is made all possible ratios between each pair of lights.

  We then conclude whether or not the body area is alive according to the difference between the measured luminance ratios and the ratios predicted by a reflectance model in the case of a living body area.

  Indeed, the reflectance model is determined using the knowledge of the reflectance of the body region of a living carrier for each wavelength, as well as the knowledge of the spectral composition of the light of each beam. .

  More specifically, it is determined, prior to the implementation of the method according to the invention, the variation of the reflectance of the body area 6, preferably a finger or a face, depending on the wavelength between two limiting wavelengths? i and 2 ^, 2. A reflectance model of reflected luminances and ratios for a body area of a living carrier is then deduced.

  Preferably, the intensity of each beam is adjusted so that the luminance reflected by the body area of the wearer is substantially constant between the regions illuminated by the different beams, and preferably over the entire surface of the body area. Thus, the intensity variations in the image of the print are solely due to the texture of the print itself, and not to the light emitted.

  In addition, the intensity of each beam is adjusted so that the luminance reflected by the region of the body area of the wearer illuminated by the beam is substantially identical to the luminances reflected by the regions illuminated by the other beams.

  Preferentially, the limiting wavelengths XI and 21.2 determine a wavelength band between 350 nm and link.

  It should be noted that the reflectance between the two limiting wavelengths X1 and 22 is represented arbitrarily and only illustratively in FIG. 2 by a line with increasing slope.

  In order to obtain a reflected constant luminance reflected by a finger of a carrier living between the two limiting wavelengths XI and 21.2, and as shown in FIG. 4, it is determined the variation of the the emitted light intensity (l emitted, 12 emitted) between the two limiting wavelengths Xi and 21.2 (see FIG.

  Thus, if for a first given wavelength, the luminance reflection coefficient is higher than the luminance reflection coefficient for a given second wavelength, the luminous intensity emitted for the first given wavelength will be smaller than the luminous intensity emitted for the second given wavelength, the reflected luminance for the first given wavelength being equal to the reflected luminance for the second wavelength given in the case of an imprint digitally belonging to a living carrier.

  In the case of a finger not belonging to a living carrier or a finger replication, the luminance reflected by the finger is not constant over the wavelength range of the light beams emitted, and is example of the type shown in Figure 5.

  Thus, in the case of a living finger, there is obtained on the camera 3 an image whose reflected luminance is independent of the illumination or the intensity emitted over the entire surface and includes the information of the grooves of the impression digitalis. Indeed, the reflected luminance is modulated by the information of the biometric characteristics, for example the grooves, of the body zone 6.

  In the case of false fingers or dead fingers, the amount of light reflected by the finger will be different depending on the colors (or wavelengths) of the light sources 4, 5.

  The constraint on the luminances emitted according to the invention offers the possibility of detection of the living character and the acquisition of the biometry considered simultaneously (for example: imprint, face).

However, although the example described preferably relates to obtaining a constant reflected luminance between two limiting wavelengths XI and X2, it is understood that the principle of the invention relates above all to the comparison of the luminance measured on different areas of the image illuminated by light beams having a different spectral composition. Indeed, the contribution of the reflected luminance constant is to allow the acquisition of the biometry considered in a single acquisition without quality degradation, which allows to determine, simultaneously, the living character of the body area, as well as the acquisition of this biometry.

Claims (7)

  1. A method for determining the living character of a body area, characterized in that it consists in: illuminating the body area using at least two light beams emitted respectively to different spectral components between two lengths of light; limit waves XI and 2.2, arranged in such a way that each beam illuminates a different part of the body area; measuring the luminance reflected by the body area in each of the areas illuminated by the at least two beams; analyzing the reflected luminances as a function of the wavelengths used by comparing, among themselves, the reflected luminances measured for each illuminated area; setting the reflected luminances measured in each illuminated area as ratios; to conclude whether or not the body area is alive according to the difference between the ratios of the measured reflected luminances and the ratios predicted by a reflectance model in the case of a living body area.   2. Method according to claim 1, characterized in that the intensity of each beam is adjusted so that the luminance reflected by the body area of the wearer is substantially constant between the regions illuminated by the different beams and in that intensity of each beam is also adjusted so that the luminance reflected by the region of the body area of the wearer illuminated by the beam is substantially identical to the luminances reflected by the regions illuminated by the other beams, thanks to which it is determined the living character of the wearer of the body zone at the same time as the capture of the biometry of the body area. 10 15 20   3. Method according to claim 1 or 2, characterized in that it comprises a step of transmitting the different beams from a source in front of which is placed a device capable of projecting several beams of different spectral components.   4. Method according to any one of the preceding claims, characterized in that the limiting wavelengths Il and X2 determine a wavelength band between 350 nm and 1 m.   5. Method according to any one of the preceding claims, characterized in that the luminance reflected by the body area is detected by means of a luminance detection device of the camera type (3).   6. Method according to any one of the preceding claims, characterized in that it comprises the step of placing the body zone (6) at a distance without contact of a biometric capture optical device (1).   7. Biometric capture optical device for implementing the method according to any one of the preceding claims, characterized in that it comprises a camera type luminance detection device (3) and at least one light source (4). , 5) capable of projecting at least two light beams.