EP1344183A1 - Dispositif pour enregistrer les sillons papillaires d'un doigt - Google Patents

Dispositif pour enregistrer les sillons papillaires d'un doigt

Info

Publication number
EP1344183A1
EP1344183A1 EP01271936A EP01271936A EP1344183A1 EP 1344183 A1 EP1344183 A1 EP 1344183A1 EP 01271936 A EP01271936 A EP 01271936A EP 01271936 A EP01271936 A EP 01271936A EP 1344183 A1 EP1344183 A1 EP 1344183A1
Authority
EP
European Patent Office
Prior art keywords
light
transparent body
finger
detector
papillary
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Withdrawn
Application number
EP01271936A
Other languages
German (de)
English (en)
Inventor
Martin Spycher
Annie-Sophie Golsong Roosdorp
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
FingerPIN AG
Original Assignee
FingerPIN AG
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by FingerPIN AG filed Critical FingerPIN AG
Priority to EP01271936A priority Critical patent/EP1344183A1/fr
Publication of EP1344183A1 publication Critical patent/EP1344183A1/fr
Withdrawn legal-status Critical Current

Links

Classifications

    • GPHYSICS
    • G06COMPUTING; CALCULATING OR COUNTING
    • G06VIMAGE OR VIDEO RECOGNITION OR UNDERSTANDING
    • G06V40/00Recognition of biometric, human-related or animal-related patterns in image or video data
    • G06V40/10Human or animal bodies, e.g. vehicle occupants or pedestrians; Body parts, e.g. hands
    • G06V40/12Fingerprints or palmprints
    • G06V40/13Sensors therefor
    • G06V40/1324Sensors therefor by using geometrical optics, e.g. using prisms
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61BDIAGNOSIS; SURGERY; IDENTIFICATION
    • A61B5/00Measuring for diagnostic purposes; Identification of persons
    • A61B5/117Identification of persons
    • A61B5/1171Identification of persons based on the shapes or appearances of their bodies or parts thereof
    • A61B5/1172Identification of persons based on the shapes or appearances of their bodies or parts thereof using fingerprinting

Definitions

  • the invention relates to a device for optically recording and creating a contrast image of the papillary grooves on the surface of a finger. It is used, for example, in a system for access control for the identification or verification of people.
  • the optical recording of the papillary grooves in particular the internal total reflection of light rays on the surface of the wrestler, which is placed on a transparent body, is used.
  • Such devices for optically recording a contrast image of the papillary grooves of a finger have a prism or a similar transparent body, on the surface of which the finger is placed.
  • the papillary grooves of the finger to be imaged are illuminated by a light source, which is arranged below the prism and shines its light through the transparent body and onto the papillary grooves.
  • This phenomenon is used for the optical recording of the papillary grooves of a finger by means of total internal reflection.
  • a typical arrangement is disclosed for example in Optics & Photonics News, October 2000, pp.24-25.
  • a light source is directed onto one of the 45 ° surfaces of a prism, so that its light falls through the prism from below onto the hypotenuse of the prism, the angle of incidence on the hypotenuse being greater than the critical angle for total internal reflection.
  • a finger lies on the surface of the hypotenuse, but the finger is not in even contact with the prism. This is because only the peaks of the grooves of the papillary grooves on the finger skin are in contact with the prism, and the valleys of the grooves are a small distance from the prism surface.
  • Such an arrangement for receiving the papillary grooves of a finger enables a high-contrast image of the papillary grooves if the finger is dry and there is air in the valleys of the grooves.
  • the finger is wet or oily, which often occurs in practice, for example on warm days, the condition for total internal reflection has changed, since water or oil is now on the prism surface and especially in the valleys of the grooves instead of air.
  • the critical angle for total internal reflection is then larger than in the case of air on the prism surface due to the higher refractive index of water or oil.
  • the light also experiences total internal reflection prevented in the areas of the valleys and emerges from the prism and into the water or oil. So it is no longer reflected.
  • the contrast of the image is largely lost.
  • the image is further distorted by light that scattered on the skin surfaces after penetration of the water or oil and gets back into the prism. Presentation of the invention
  • the present invention is based on the object of providing a device for recording an optical contrast image of a papillary groove pattern of a finger, in which the light on the contact surface for the finger experiences total internal reflection.
  • the disadvantages of the prior art mentioned should be avoided and a high contrast of the image of the papillary groove pattern should be achieved, regardless of the properties of the finger surface, such as, for example, wet or dry.
  • the device has a transparent body with an interface, which serves as a support surface for the finger surface to be imaged.
  • a light source is arranged so that its light shines through the transparent body and falls on the interface of the body on which the finger lies.
  • the device has a light detector and imaging optics, the optical axis of which leads through a side surface of the transparent body. According to the invention, the angle of incidence of the light from the light source onto the interface is smaller than the critical angle for total internal reflection at the interface of the transparent body with air above it.
  • the imaging optics are designed in such a way that they only capture light rays and direct them onto the light detector, which emanate from the contact surface of the transparent body at an angle to the normal to the contact surface that is equal to or greater than the critical angle for total internal reflection at the interface between the transparent body with water, oil or similar medium on it.
  • the light that falls from the light source through the transparent body onto the interface largely passes through the interface and to the finger on it, since the angle of incidence of the light is less than or equal to the critical angle for total internal reflection at the interface. (Only a small part, approx. 4%, of the light emitted by the light source is specularly reflected.)
  • the light is scattered on the surface of the papillary grooves or inside the finger.
  • the light scattered inside the finger is partially totally internally reflected at the interface between the finger and air, water or oil and creates an evanescent field on the finger surface, which decays exponentially into the space outside the finger surface.
  • the evanescent Decay distance or 1 / e depth is the distance from the finger surface at which the field strength of the electromagnetic field is still 1 / e the field strength of the electromagnetic field on the finger surface.
  • the surfaces of the mountains of the papillary grooves are located near the contact surface, the distance between their surfaces and the contact surface being smaller than the evanescent or in the region of the evanescent decay distance.
  • the evanescent fields emanating from the mountains of the papillary grooves produce propagating waves that radiate into the transparent body.
  • the entry angle of the propagating waves generated by evanescent fields in the contact surface is equal to or greater than the critical angle for total internal reflection.
  • the evanescent fields emanating from the valleys of the papillary grooves are too far away from the contact surface to be able to generate propagating waves with a still significant field strength in the transparent body. Since the field strength decreases exponentially with the distance from the corresponding finger area to the contact surface, there is a high contrast between the mountains and the valleys of the papillary grooves.
  • the imaging optics are arranged in such a way that they only direct light from the contact surface or its object surface onto the light detector, which propagates within the angular range for total internal reflection, in this area light rays propagate through the excitation of evanescent fields between the mountains of the grooves and the Interface arise.
  • Evanescent light waves emanating from the areas of the valleys of the papillary grooves are unable to produce any propagating light waves of perceptible field strength in this angular range. There is therefore no light from the valleys that can be propagated in this angular range and detected by the light detector. This creates a contrast image in which the mountains of the papillary grooves appear bright and the valleys dark.
  • the invention has the advantage that regardless of whether the finger is dry, wet, greasy or oily, the quality of the contrast image is retained. For example, if the finger is wet, there is water in the valleys. The light that comes from the light source into the valleys of the papillary grooves filled with water is not scattered there. As in the case of air in the valleys, it propagates through the water to the surfaces of the valleys. Since these are relatively far away from the interface, evanescent fields emanating from there in turn cannot propagate light waves in the angular range for total reflection cause. So even in the case of a wet finger there is no light from the valleys in the angular range in which the imaging takes place. Evanescent fields are excited in the space between Rillenberge and the interface, regardless of whether the finger surface is wet or dry.
  • the critical angle for total internal reflection differs depending on the medium of the transparent body and the medium on top of it.
  • the critical angle & k r j in the case of water on the finger and on the interface in the areas of the valleys is greater than in the case of air above the interface.
  • the imaging optics and the light detector are designed such that they detect light from the angular range for internal total reflection in the case of water. With this design, the propagating light waves are detected at the interface both in the case of water and in the case of air, since the critical angle in the case of air is smaller than the critical angle in the case of water.
  • the angular range for total internal reflection in the case of water largely coincides with the angular range for total internal reflection in the case of air.
  • the critical angle in the case of water is 62 ° and in the case of air 42 °, the angle range for total internal reflection, measured from the normal to the interface, ranging from 62 ° to 90 ° or from 42 ° to 90 °.
  • the contrast of the image of a wet finger hardly differs from the contrast of the image of a dry finger.
  • the angular range for total internal reflection is different for the two applications mentioned, other factors such as a different 1 / e depth contribute to achieving a comparable contrast in the images.
  • the light source has one or more lenses for collimation or quasi-collimation of the light transmitted to the interface. This means that no light from the light source comes directly into the angular range for total internal reflection in the imaging optics and onto the light detector.
  • the light source has a plurality of light-emitting diodes which are arranged in a one- or two-dimensional array.
  • the arrangement in an array ensures homogeneous illumination of the Interface of the transparent body. While the light emitted by a single light-emitting diode onto a surface often has dark rings, the arrangement of several light-emitting diodes in an array achieves a homogeneous intensity distribution in that the dark rings of the individual light-emitting diodes are illuminated by adjacent light-emitting diodes in the array. Furthermore, thanks to the lenses integrated in the light-emitting diodes, the emitted light is quasi-collimated or almost collimated.
  • the light-emitting diodes are arranged in such a way that the intensity distribution in the plane of the light detector is homogeneous. Since the intensity of the light falling on the detector is inversely proportional to the square of the path covered by the light, the light-emitting diodes are arranged between the light source and the detector in accordance with the different length of the light path. In a first variant, the light-emitting diodes are arranged in two rows, the emitted intensity of one row corresponding to 70-80% of the emitted intensity of the second row.
  • the light-emitting diodes are arranged in three rows, the transmitted intensity of the middle row being approximately 30-70%, in particular approximately 50%, of the transmitted intensity of the first and third rows.
  • the light-emitting diodes emit in the red wavelength range from 650 nm to 780 nm. In a further embodiment, the light emitting diodes emit in the infrared wavelength range from 780 nm to 980 nm.
  • the use of infrared light-emitting diodes has the advantage of a more advantageous energy balance for the entire device, since the light intensity emitted per current consumption of the light-emitting diodes is greater than that of red light-emitting diodes. Furthermore, the sensitivity of suitable detectors is higher in this wavelength range.
  • a diffuser is arranged between the light source and the transparent body.
  • the use of a diffuser also results in a homogeneous intensity distribution of the light on the interface of the transparent body. It also has the advantage that fewer LEDs are required for a desired homogeneity of the intensity distribution on the interface.
  • the imaging optics have a single lens or a lens system for imaging the papillary groove pattern on the detector surface. Conventional lenses as well as holographic lenses can be used for this.
  • a single focusing lens is integrated on one side surface of the transparent body.
  • the imaging optics have an aperture to improve the depth of field of the image on the detector surface.
  • this diaphragm is arranged immediately before or after the individual integrated lens.
  • the optical axis of the imaging optics leads perpendicular to the side surface of the transparent body, so that there is no light refraction on the side surface, which could distort the image of the papillary groove pattern.
  • a mirror is arranged on a side surface of the transparent body, which directs the light emanating from the support surface back into the transparent body.
  • the mirror is a flat mirror
  • a convex, cylindrical mirror which allows the light in the transparent body to diverge slightly.
  • the cylindrical mirror provides the advantage of imaging on the detector surface, in which the entire detector surface is fully illuminated.
  • a further deflection mirror is arranged outside the transparent body, which directs the light that passes through the individual lens integrated on the side surface of the body onto a board on which the light-emitting diodes and the detector are arranged. This arrangement then allows all electrical components, the light-emitting diodes and the detector to be arranged on a common printed circuit board.
  • a further increase in efficiency is possible by arranging mirrors on the other side walls as well, which light which is not usefully directed onto the detector (for example, coming from the critical angle but not falling on the lens) is directed onto the detector a second time Finger is guided.
  • the mirroring can, if necessary, be stepped or the like in order to optimize the return of the light. All of these measures for the imaging optics, namely the deflection mirror on the side surface and the focusing lens integrated on another side surface, and the second deflection mirror and the use of a common board serve to miniaturize the imaging optics and implement the device, so that the sensor is suitable in one small housing.
  • the light detector of the device has a two-dimensional CMOS camera. It enables the recorded data to be processed relatively easily, for example for image processing for the purpose of identifying or verifying a person in the context of a system for access control or access control to a device.
  • the light detector of the device has a CCD camera.
  • the support surface is oriented at an angle of less than 90 ° to the optical axis of the imaging system.
  • the detector surface is also oriented at an angle to the optical axis.
  • the application of the Scheimpflug principle reduces distortions in the image.
  • the arrangement according to this principle causes a reduction in the light intensity on the detector surface.
  • the transparent body is made of a highly refractive material. This causes the critical angle for total internal reflection to become smaller since the refractive index of the denser medium becomes larger.
  • the transparent body consists of a particularly high-index plastic such as PMMA
  • the proposed optics for measuring the papillary grooves can advantageously be done with a pulse measurement or even a measurement of the oxygen content in the blood of the patient analyzed fingers can be combined (so-called life test). Furthermore, in order to save electricity when there is no finger on the detector, the lighting can be switched off except for a light source.
  • This one diode for example, in combination with an associated detector, which can either be designed as a separate detector or can also exist in the detector for the papillary grooves, then takes over a monitoring function (light barrier). Periodically, light is emitted by the light source, and as soon as the detector receives corresponding reflected signals, the other light sources, which serve to illuminate the papillary grooves, are switched on and the entire unit is activated.
  • FIG. 1 shows a representation of the device for recording the papillary grooves of a finger with the light source and imaging optics
  • Figure 2 shows an example of a recording of the papillary grooves of a dry
  • Figure 3 shows an example of a recording of the papillary grooves of a wet finger.
  • Figure 4 shows an example of a special and preferred embodiment of the device according to the invention with a miniaturized imaging optics integrated in the transparent body, one
  • Figure 5 shows another view of the transparent body with integrated
  • FIG. 6 shows the mirror holder of the device according to the invention
  • FIG. 7 shows the printed circuit board with an example of the arrangement of the
  • Figure 1 shows a transparent body 1, for example made of glass, quartz glass, or plexiglass. Its interface 2 serves as a support surface 2 for a finger. Papillary grooves with mountains 3 and valleys 4 are shown here in greatly enlarged form in contact with the contact surface 2. The space between the boundary or contact surface 2 and the surfaces 5 of the valleys 4 are filled with air, water, oil and other clear liquids that can be on a person's finger. The depth of the valleys is typically 1/10 mm, which is much deeper than a typical 1 / e depth.
  • a light source 8 is arranged under the transparent body 1, the emerging light being directed perpendicular to the interface 2.
  • the light source 8 consists, for example, of one or more light-emitting diodes 8, each of which has an integrated lens. The emerging light is largely collimated by these lenses, with some of the light being emitted in an angular range of, for example, 30 °. In any case, the angle of incidence of the light on the interface 2 is less than the critical angle
  • Light rays 9 from the light source pass through the transparent body and through the interface 2 onto the surface of the papillary grooves and into the finger, i. H. in the interior of the mountains 3 of the papillary grooves.
  • the light is scattered there, and light beams 10 arise in all directions.
  • evanescent fields are excited, which generate waves 11 propagating in the transparent body 1. These propagate at angles (measured from the normal) that are greater than / equal to the critical angle for internal ones
  • the imaging optics are designed in such a way that only light rays in the light bundle 12, which emanate from the evanescent fields and propagate in an angular range for internal total reflection, are detected.
  • the beams in the bundle 12 lie clearly within the angular range for total internal reflection at the interface 2 with water in the valleys 4.
  • the light waves propagate in an angular range for total internal reflection from 42 ° to 90 °. Only the light rays in the angular range from 62 ° to 90 ° reach the detector.
  • the imaging optics effect an imaging of the papillary grooves on the detector surface of the light detector 22 with a reduction of 4x, the contact surface 18 mm x 24 mm (or according to other embodiments as described further below in connection with FIGS. 4ff 11x14mm or 15x20mm) and the detector area is approx. 4mm x 6mm (eg CIF or VGA sensors).
  • the imaging optics consist of a single symmetrical lens with a focal length of 12 mm for 18x24mm.
  • the imaging optics are folded by means of a planar mirror, as a result of which the device can be made more compact. Furthermore, folding by means of a curved mirror can also be implemented with the lens being omitted.
  • the total system length of the imaging optics is 80 mm in the example shown.
  • the aperture aperture is, for example, 1 mm.
  • the light detector 22 consists of a two-dimensional CMOS camera with an array of, for example, 640x480 pixels. With this number of pixels, sampling or quantification errors can be avoided in this application.
  • the optical axis of the imaging optics runs perpendicularly through the side surface 25 of the transparent body 1.
  • the detector surface of the light detector 22 is oriented at an angle ⁇ to the optical axis, the object surface or support surface being at an angle ⁇ to the optical axis.
  • the angles ⁇ and ⁇ are 23 ° and 61 °, respectively.
  • the transparent body is made of a highly refractive material such as SF, LaF or LaSF glasses from Schott with a refractive index between 1.65 and 1.9.
  • the use of such high-index glasses causes the critical angle ⁇
  • FIG. 2 shows a contrast image of the papillary grooves of a dry finger created by the device according to the invention. The light areas of the contrast image represent the mountains and the dark areas the valleys of the papillary grooves.
  • FIG. 3 shows a contrast image of the same but wet finger created by the same device. The contrast achieved is the same in both figures.
  • FIG. 4 shows the device according to the invention in a compact implementation with the transparent body 1, a mounting block 40 and a printed circuit board 50.
  • the imaging optics is integrated in the transparent body 1.
  • the transparent body 1 has a contact surface 2, on which the finger, the papillary grooves of which are imaged, is placed.
  • the support surface 2 is illuminated from below by a light source which is arranged on the printed circuit board.
  • the rays emanating from the finger fall on a side surface 25 of the transparent body, on which a mirror 30 is integrated.
  • the mirror can be put on, or preferably evaporated directly onto the material of the transparent body.
  • this mirror 30 is cylindrically convex. However, it can also be flat.
  • the lens After reflection on the mirror 30, the rays reach the other side surface 31 of the transparent body, on which a focusing lens 32 is integrated.
  • Integrated means that the lens is either attached directly to the transparent body in a substantially form-fitting manner, or else is worked out from the block of the transparent body, ie the lens and transparent body are designed as a monobloc.
  • the integrated lens is preferably arranged essentially flush with the lower edge of the block 1.
  • the cylindrical mirror has the effect that the rectangular, light-sensitive detector surface of the device is fully illuminated and used.
  • FIG. 5 shows the same transparent body from FIG. 4, but in a view of the side surface 31 with the lens 32 integrated there.
  • the block 1 typically has a length L of 27.5 mm with a width B of 22 mm and a height H of 6, 1 mm.
  • a larger embodiment has the dimensions 37.3 mm (L), 28 mm (W) and 8.2 mm (H).
  • the side surface designated by 25, in which the mirror 30 is integrated, is inclined against the support surface 2, so that the light beams directed from the support surface 2 onto the mirror 30 pass parallel to the support surface 2 on the opposite side through the integrated lens 32 and so Distortions can be avoided.
  • the angle between Support surface 2 and side surface 25 is not 90 degrees in the specified mafia of the transparent body maW but in the range of 83 degrees. In the larger embodiment, this angle is 82 degrees.
  • the mirror 30, too which is integrated in this inclined side surface 25, has a shape which prevents the image of the finger resting on the support surface 2 from being as distorted as possible (ie preferably a rectangular image with a rectangular finger support surface).
  • This shape can, for. B. be cylindrical, but can also take a more complex shape, which is calculated from the paths of the light rays between the contact surface 2 and the detector.
  • Figure 6 shows the mounting block 40. It has a frame 41 on which the transparent body comes to rest. In a side part 43, which abuts the side surface 31 of the transparent body, an aperture 44 and a deflecting mirror 45 are arranged. The deflecting mirror 45 directs the light, which has been focused by the lens 32 and has passed through the aperture 44, down to the printed circuit board 50 according to FIG. 7. On the printed circuit board 50 there are several light-emitting diodes 51 in rows and the light detector 22 with the rectangular light-sensitive one Detector surface 23 arranged. In the example shown, the LEDs are arranged in three rows. It is preferred to effect homogeneous illumination of the detector surface 23.
  • the light path lengths of different rays that come from the light source to the support surface of the transparent body and via mirror and lens to the light detector are very different. If the intensity of all light-emitting diodes were the same, the intensity distribution on the light detector would be correspondingly inhomogeneous due to the intensity falling with the square of the light path length. For this reason, in a preferred method for operating the device, the light-emitting diodes are driven to different extents.
  • the light-emitting diodes of the arrangement shown are activated, for example, such that the outgoing intensity of the middle row is 50% of the intensity of the two outer rows.
  • the outgoing intensity of one row is approximately 80% of the intensity of the other row.
  • the diodes 51 it is also possible to cover only the two outer rows, in which 3 or 4 diodes are arranged, with diodes which serve to illuminate the papillary grooves.
  • a further light-emitting diode and a separate detector can then be arranged in the middle row. This special LED in the middle row can then function as a Take over the light barrier. So that normally only this diode is activated and periodically emits light signals. Only when a finger is placed on the support surface 2 is the light reflected by this diode and received by the separate detector.
  • this separate detector receives a signal, the rest is activated, ie the other diodes used to illuminate the papillary grooves are switched on and the measurement of the papillary grooves is activated. Since the diodes normally consume a lot of current, and therefore permanent illumination of the support surface 2 should be avoided, the power consumption of the unit can be significantly reduced by only illuminating when a finger is effectively lying on the support surface 2.
  • the separate detector does not necessarily have to be illuminated directly, but can also be illuminated indirectly using an optical guide which prevents ambient light from interfering with the measurement. This diode arranged in the middle row can also be used for a so-called life test (eg pulse oximetry).
  • Transmitters and / or receivers for pulse oximetry can also be arranged on the side of the block. That means it can be used e.g. B. measure the pulse and / or the oxygen content in the blood of the finger placed on it to ensure that a living finger and no artificial replica rests on the support surface 2. Work the diodes provided for illuminating the contact surface z. B. at a frequency of 650 nm, another frequency is necessary to measure the oxygen content. The diode in the middle row can z. B. operated at a frequency of 850 nm, and the oxygen content can be determined by comparing the two measurements on two different frequencies. The two different ones
  • Frequencies can be measured on the same separate detector.

Landscapes

  • Engineering & Computer Science (AREA)
  • Physics & Mathematics (AREA)
  • Optics & Photonics (AREA)
  • Human Computer Interaction (AREA)
  • General Physics & Mathematics (AREA)
  • Multimedia (AREA)
  • Theoretical Computer Science (AREA)
  • Image Input (AREA)
  • Measurement Of The Respiration, Hearing Ability, Form, And Blood Characteristics Of Living Organisms (AREA)
  • Length Measuring Devices By Optical Means (AREA)

Abstract

L'invention concerne un dispositif pour l'enregistrement optique des sillons papillaires à la surface d'un doigt. Ce dispositif présente un corps transparent (1) comportant une surface d'appui (2). La lumière provenant d'une source lumineuse (8) frappe la surface d'appui (2) selon des angles qui sont inférieurs à l'angle critique pour la réflexion totale interne sur la surface d'appui (2). Des champs évanescents sont excités au niveau des crêtes (3) des sillons papillaires du doigt. La lumière (12, 13, 14) se propageant quitte la surface d'appui (2) et frappe un détecteur de lumière (22) par l'intermédiaire d'un système optique de représentation (21). Les rayons lumineux dans le faisceau lumineux (12) quittent la surface d'appui (2) selon des angles se trouvant dans la zone angulaire des rayons lumineux totalement réfléchis de manière interne. L'avantage de ce dispositif réside dans le fait que le contraste d'un enregistrement de sillons papillaires est indépendant de l'état de la surface du doigt (mouillée ou sèche).
EP01271936A 2000-12-22 2001-11-29 Dispositif pour enregistrer les sillons papillaires d'un doigt Withdrawn EP1344183A1 (fr)

Priority Applications (1)

Application Number Priority Date Filing Date Title
EP01271936A EP1344183A1 (fr) 2000-12-22 2001-11-29 Dispositif pour enregistrer les sillons papillaires d'un doigt

Applications Claiming Priority (4)

Application Number Priority Date Filing Date Title
EP00811232 2000-12-22
EP00811232A EP1217573A1 (fr) 2000-12-22 2000-12-22 Dispositif de saisie des crêtes papillaires des doigts
EP01271936A EP1344183A1 (fr) 2000-12-22 2001-11-29 Dispositif pour enregistrer les sillons papillaires d'un doigt
PCT/CH2001/000689 WO2002052491A1 (fr) 2000-12-22 2001-11-29 Dispositif pour enregistrer les sillons papillaires d'un doigt

Publications (1)

Publication Number Publication Date
EP1344183A1 true EP1344183A1 (fr) 2003-09-17

Family

ID=8175099

Family Applications (2)

Application Number Title Priority Date Filing Date
EP00811232A Withdrawn EP1217573A1 (fr) 2000-12-22 2000-12-22 Dispositif de saisie des crêtes papillaires des doigts
EP01271936A Withdrawn EP1344183A1 (fr) 2000-12-22 2001-11-29 Dispositif pour enregistrer les sillons papillaires d'un doigt

Family Applications Before (1)

Application Number Title Priority Date Filing Date
EP00811232A Withdrawn EP1217573A1 (fr) 2000-12-22 2000-12-22 Dispositif de saisie des crêtes papillaires des doigts

Country Status (3)

Country Link
US (1) US7315632B2 (fr)
EP (2) EP1217573A1 (fr)
WO (1) WO2002052491A1 (fr)

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US20040114783A1 (en) 2004-06-17
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WO2002052491A1 (fr) 2002-07-04

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