• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    The invention relates to a security document comprising a support (2, 102, 202) comprising at least one security element (3, 103, 203). According to the invention, the security element comprises a film (4, 110, 220) with interference effects The invention relates to a method for determining the authenticity of such a document and to an apparatus for carrying out such a method.
    公开号:AT517776A2
    申请号:T9389/2014
    申请日:2014-10-07
    公开日:2017-04-15
    发明作者:Beauchet Frédéric
    申请人:Banque De France;
    IPC主号:
    专利说明:

    SAFETY DOCUMENT COMPRISING A FILM WITH INTERFERENCE EFFECTS, METHOD FOR DETERMINING THE AUTHENTICITY OF SUCH A DOCUMENT, AND A DEVICE FOR CARRYING OUT ONE
    SUCH PROCEDURE
    The invention relates to a security document comprising a film with interference effects, a method for determining the authenticity of such a document and an apparatus for carrying out such a method.
    TECHNOLOGICAL BACKGROUND OF THE INVENTION
    Banknotes are known which comprise a carrier which contains at least one security element. The security element is printed on the banknote by means of a color designated OVI (for optically variable color, i.e. color with optically variable effects). The security element thus has a different color depending on the orientation in which the security element is viewed.
    However, the security elements printed from OVI colors change color slightly according to the orientations in which they are viewed.
    Further, printing the security element with an OVI color makes the security element opaque. When considering the bill in transmission, i. if one illuminates one of the sides of the banknote and looks at the other side of the banknote, the security element does not allow light to pass: consequently, even if the viewing angle changes, there is no color change of the security element, and the variable optical effects of the security element are consequently lost.
    OBJECT OF THE INVENTION
    An object of the invention is to propose a security document comprising a security element with interference effects, which is more difficult to reproduce than the security elements which are printed from paint of the type OVI color.
    BRIEF DESCRIPTION OF THE INVENTION
    To achieve this aim, a security document is proposed which comprises a carrier which contains at least one security element.
    According to the invention, the security element comprises a colored, translucent film with interference effects.
    Note that "interference effects" are understood to mean that the film has optical properties, such as: - the film has a different color, depending on the orientation in which the film is viewed, - the film has at least certain different illuminations and a different color at the same viewing angle of the film.
    The film with interference effects is sufficiently transparent to allow the transmission of light rays therethrough and to allow a sharp representation of objects therethrough. The film is therefore colored, but not opaque.
    Thanks to the film with interference effects, the security element according to the invention has the advantage of being much more sensitive to the direction of the light rays passing through it than the security elements of the prior art, which are printed from OVI color. Thus, the security element may take a variety of different colors according to the orientations in which it is viewed.
    Due to this variety of different colors, it is much more difficult to fraudulently reproduce the security element. Consequently, even the fraudulent printing of the security document with special inks does not make it possible to reproduce such a variety of colors.
    Moreover, the security element has color variations both in the case of different alignment of the security element and when the security element is differently illuminated (different angles of illumination, different kind of light, possibly lighting the rear side of the security document instead of the front side of the security document).
    Consequently, it proves to be particularly difficult to fraudulently reproduce the security document and these multitude of colors.
    Thanks to the fact that the film is sufficiently transparent, it is possible to detect the changes in the color change of the security element by reflection (examination of one side of the security document without illumination of the other side of the security document, ie examination of the rays reflected from the security document) also by transmission (examination of one side of the security document with illumination of the other side of the security document, ie the examination of the beams broken and transmitted by the security document).
    To confirm the authenticity of the security document, it is therefore possible to verify the color changes by reflection or transmission. Thus, one has a possible double verification, which is not feasible with the printed by means of OVI colors security elements of the prior art. Therefore, it is much more difficult to fraudulently reproduce the security element without exposing that fraud.
    Furthermore, a method for determining the authenticity of such a security document is proposed that comprises the successive steps of: illuminating a first side of the security document at a first angle of incidence with a wavelength range centered around a first wavelength and determining at least one variable that representative of a first light beam reflected from the security document, illuminating the first side of the security document at a second angle of incidence different from the first angle of incidence, and having a wavelength range centered about a second wavelength that is is different from or identical to the first wavelength, and determining at least one variable representative of a second beam of light reflected from the security document, - assessing the authenticity of the security document in dependence on determined variables, - indicate whether the security document is genuine or not.
    Furthermore, an apparatus for carrying out the aforementioned determination method is proposed, which comprises at least a first radiation source and a second radiation source, which are spaced from each other and inclined relative to each other with respect to the first side of the security document, and at least first means for determining variables of the light rays emitted by the Security document are reflected, wherein the first determining means are arranged opposite the first side of the security document.
    BRIEF DESCRIPTION OF THE DRAWINGS
    The invention will be better understood from the following description of an embodiment not limiting the invention with reference to the accompanying drawings, in which: Figure 1 is a perspective view of a security document according to a first embodiment of the invention; Figure 2 is a sectional view 1 is a perspective view of a security document according to a second embodiment of the invention, FIG. 4 is a sectional view of the security document shown in FIG. 3, FIG. 5 is a perspective view of a security document according to FIG FIG. 6 is a schematic side view of an apparatus for carrying out a method for detecting a security document shown in FIG.
    DETAILED DESCRIPTION OF THE INVENTION
    With reference to FIGS. 1 and 2, the security document according to the first embodiment is a banknote 1 in the present case. The banknote 1 comprises a carrier 2 which contains a security element 3. The thickness of the banknote and the security element are clearly exaggerated in FIGS. 1 and 2 in order to facilitate the intelligibility of said figures. The carrier 2 thus has a thickness of 100 microns substantially.
    According to the invention, the security element 3 comprises a film 4 with interference effects.
    A part of the film 4 is here integrated in the thickness of the carrier 2, so that a first main side of the film 4 is visible and the second main side of the film 4, which faces away from the first main side, is embedded in the thickness of the carrier 2, The Foil 4 appears on the surface of the carrier 2.
    In particular, the banknote 1 comprises an opening 5, which passes through the thickness of the carrier 2, so that a part of the second main side of the film 4 remains visible through this opening 5.
    Preferably, the film 4 is a multilayer film having a thickness of less than 50 microns.
    Each layer of the film 4 comprises a sheet, each sheet having a refractive index different from that of the two sheets which frame it. Such a film comprises tens to several hundreds of leaves, giving it very special optical properties. Because in this way, each light beam illuminating the film 4 is reflected by each sheet forming the film 4 in a different way, resulting in a multi-color reproduction: different portions of the film 4 have at the same viewing angle of one of the main surfaces of Carrier 2 different colors. Depending on the angle of incidence with which the light rays reach the film 4, the multi-color reproduction of the film 4 is also different. Therefore, it is precisely the structure of the film 4 that gives it its special properties, and not the material that forms each of the layers. In particular, it is the sequence of the various layers with the different refractive indices which gives the film 4 its special properties, although each layer has no special property. Preferably, the film 4 has an asymmetric structure in a plane P of the film 4 which is parallel to the two major sides of the film 4 and which extends in the center 4 of each film, i. in the middle of the thickness of the film 4.
    For example, when the film 4 comprises a first series of sheets and a second series of sheets arranged on either side of a central sheet, the first series of sheets has refractive indices different from those of the second series of sheets.
    Thus, the multi-color rendering of the film 4 is equally different, depending on whether one illuminates one or the other of the main sides of the carrier 2.
    Looking at the first main side of the carrier 2 (corresponding to the first main side of the film 4) and illuminating the first main side of the carrier 2, one sees a first multi-colored reproduction of the film 4. When looking at the first main side of the carrier 2 and one illuminates the second main side of the support 2 (which faces away from the first main side of the support 2), one sees a second multi-colored reproduction of the film 4, wherein the reproduction in the region of the part of the film 4, which covers the opening 5, is brighter. Looking at the second main side of the carrier 2 and illuminating the second main side of the carrier 2, a third multicolor reproduction of the foil 4 in the region of the opening 5 is seen. Looking at the second main side of the carrier 2 and the first main side of the carrier 2 lit, you can see a fourth multi-colored reproduction of the film 4, which is shining in the area of the opening 5.
    The very special optical properties of the film 4 make the fraudulent reproduction of the security element 3 and consequently the banknote 1 difficult.
    The security element comprises in the present case a marking 6, which is supported by the first main side of the film 4. The mark 6 is here a bar code.
    The barcode thus enables an additional saving of the security element.
    The bar code is applied, for example, by means of printing on a fluorescent dye, which is preferably transparent in the visible spectrum.
    For example, the label 6 is printed by means of a fluorescent dye under UV light (for example, fluorescent white). When illuminating the first major side of the carrier 2 with a light having a wavelength range extending between ultraviolet and part of the visible spectrum, and viewing the first major side of the carrier 2 at different angles, the film 4 becomes due to its optical Properties change the colors, but the marker will remain white. Now, if one illuminates the first main side of the carrier 2 with a light having a wavelength range extending between ultraviolet and a part of the visible spectrum, and viewing the second main side of the carrier 2 from different angles, the film 4 becomes due to their optical properties change the colors and also in the area of the marking 6 have different colors, the colors in the region of the marking 6 differ from those of the rest of the film 4, since the passage of the ultraviolet rays and the rays of the part of the visible spectrum through the Dye of the label 6 changes the properties of the film 4.
    The dye of the label 6 thus allows a local change in the optical properties of the film 4. This makes the fraudulent reproduction of the security element then particularly difficult.
    A second embodiment of the invention will be described below with reference to FIGS. 3 and 4. The thickness of the banknote and the security element are clearly exaggerated in FIGS. 3 and 4, in order to facilitate the intelligibility of said figures. The elements common to the first embodiment retain their numbering increased by 100.
    The security element 103 here comprises a film with interference effects, which is formed into a thread 110. The thread 110 is formed in the backing as a "suture." This term is well known in the art of banknotes and means that the suture 110 is formed in the backing so that the first portions of the suture are completely in the thickness of the backing 102 The second portions of the thread are exposed on the surface of the first main side of the carrier 102, these second portions are consequently visible in the region of the first main side of the carrier 102. The first portions and the second portions extend successively in the carrier 102.
    The security element here comprises a coating 115 which has a structure that acts like a diffraction grating. In particular, the cover 115 completely covers one of the sides of the thread 110, so that it is visible in the region of the second sections of the thread 110.
    It should be noted that a diffraction grating is an optical device composed of a series of parallel columns (transmission grating) or reflecting grooves (reflection grating): when white light reaches the grating, the grating disassembles the light in the manner of a prism.
    Thus, due to its particular structure, the cover 115 adds rainbow color plays to one of the sides of the thread 110. As a result, the coating 115 changes the optical characteristics of the thread 110 on only one side of the thread 110, which makes the fraudulent reproduction of the security element 103 according to this second embodiment particularly difficult.
    Thus, different portions of the coating 115-strand unit 110 have different colors at a same viewing angle from one of the sides of the carrier 102. Depending on the angle of incidence at which the light rays reach the coating 115-thread 110 unit, the unit is multicolored Plating 115 - thread 110 also different.
    Further, the multi-color rendering of the unit 115 of overlay 115 - thread 110 is different, depending on whether one illuminates one or the other of the main sides of the carrier 102. Because of the arrangement of the coating 115 on only one side of the thread 110, the security element then has an asymmetrical structure in a plane P 'of the security element which is parallel to the two main sides of the security element and which extends in the middle of the security element. Accordingly, since the other side of the thread 110 is not covered by any coating, the light path of the rays transmitted through the carrier 104 in one direction and the other is not the same.
    Looking at the first major side of the carrier 102 and illuminating the first major side of the carrier 102, one sees a first multicolor reproduction of the second portions of the unit 115 of overlay 115 - thread 110. Considering the first major side of the carrier 102, and viewing Figs second main page of the carrier 102, one sees a second multi-colored reproduction of the second portions of the unit 115 of cover 115 - thread 110. Looking at the second main side of the carrier 102 and illuminating the first main side of the carrier 102, one sees a third multicolor Reproduction of the second sections of the unit from coating 115 - thread 110.
    It should be noted that the first sections may possibly be viewed in transmission, but their color rendering is then less recognizable than that of the second sections.
    The marking of the security element 103 in the present case is an imprinted letter 111 on every other section of the thread 110.
    A third embodiment of the invention will be described below with reference to FIG. The thickness of the bill and the security element are clearly exaggerated in Figure 5 to facilitate the clarity of the figure. The elements common to the first embodiment retain their numbering, increased by 200.
    The security element 203 here comprises a film 220 with interference effects, which is glued to one of the main sides of the carrier 202.
    The marking of the security element in the present case is a logo 221 which is printed on the film.
    A method of determining the authenticity of the bill according to the second embodiment will be described below. During a first step, a first side of the bill 101 is illuminated at a first angle of incidence with a wavelength range centered about a first wavelength. Then, the spectral response of the first light beams reflected from the banknote 101 under the effect of illumination at three different viewing angles, and the spectral response of the second beams of light from the banknote 101 under the effect of illumination are determined according to three different ones Viewing angles are broken and let through.
    Thus, the light response of the first page and the light response of the second side of the banknote 101 facing away from the first side of the banknote are examined at three different viewing angles for each of the two sides of the banknote 101. During a second step, the banknote 101 is under a illuminates at a second angle of incidence, different from the first angle of incidence, and with a wavelength range centered around a second wavelength identical to the first wavelength. Then, the spectral response of the third light beams reflected from the banknote 101 under the effect of the illumination according to the three different viewing angles, and the spectral response of the fourth light beams from the banknote 101 under the effect of illumination according to the three different ones are determined Viewing angles are broken and let through. Thus, the light response of the first side and the light response of the second side are again examined at viewing angles that are different from each other but identical to those of the first step. During a third step, the banknote 101 is illuminated at a third angle of incidence, different from the first angle of incidence, and with a wavelength range centered around a third wavelength, which is identical to the first wavelength. Then, the spectral response of the fifth light beams reflected from the banknote 101 under the effect of the illumination according to the three different viewing angles, and the spectral response of the sixth light beams from the banknote 101 under the effect of illumination according to the three different ones are determined Viewing angles are broken and let through. Thus, the light response of the first side and the light response of the second side are again examined at viewing angles that are different from each other but identical to those of the first step. During a fourth step, the authenticity of the banknote 101 is evaluated as a function of the spectral responses of the first, second, third, fourth, fifth and sixth light beams, for example by comparing each of the determined 18 spectral responses with a corresponding theoretical spectral response.
    The score may be such that all comparisons must match each other for the bill 101 to be considered genuine, or may be such that only a predetermined number of matches must be equal to each other for the bill 101 to be considered genuine. During a fifth step, it is indicated whether the banknote 101 is genuine or not.
    It is thus possible to check the authenticity of the banknote 101 by reflection (examination of the light rays reflected from the banknote and, consequently, the colors of the first side of the banknote) and by transmission (examination of the light rays which are broken and transmitted by the banknote, and consequently the Colors of the second side of the banknote).
    The inventive method for checking the authenticity of the banknote 101 is therefore particularly stringent and allows a very good detection of illegally reproduced banknotes.
    Such a process can not be carried out with a prior art security element printed on the support with an OVI color since such dyes are opaque in transmission.
    According to a particular embodiment, the method further comprises, in succession, the additional steps of: taking at least one image of at least part of the banknote 101, determining the marking 111, analyzing the authenticity of the marking 111. During the fifth step, one then indicates whether the Banknote 101 is true depending on the analysis of the spectral responses of the determined first, second, third, fourth, fifth and sixth light beams and the analysis of the authenticity of the marker 111.
    Referring to FIG. 6, in the present case, the apparatus for performing the method described above includes a first radiation source 301 for performing the first step, a second radiation source 302 for performing the second step, and a third radiation source 303 for performing the third step. The three radiation sources 301, 302, 303 are spaced from one another and inclined relative to each other opposite the first side of the banknote 101.
    The apparatus further comprises, in the present case, first determination means which here comprise three first sensors 311, 312, 313 for detecting the spectral responses of the light beams reflected by the banknote 101 for carrying out the three first steps, wherein the three first sensors 311, 312, 313 are arranged opposite the first side of the banknote 101.
    The apparatus further comprises second determining means, here comprising three second sensors 321, 322, 323 for detecting the spectral responses of the light beams refracted and transmitted by the banknote 101 for performing the first three steps. The three second sensors 321, 322, 323 are arranged opposite the second side of the banknote 101.
    Of course, the invention is not limited to the described embodiment, and you can make it embodiment variants, without departing from the scope of the invention as defined by the claims.
    Although the various security documents described herein are banknotes, the security document according to the invention may in particular be an identity card, an official paper, etc.
    The security element may have a symmetric structure in a plane of the security element which is parallel to the two parallel main sides of the security element and extends in the middle of the security element. In one embodiment, the security element may have an asymmetrical structure, which allows a much greater number of color variations of the film with interference effects according to the side of the considered security element.
    When the film is composed of a stack of sheets having different indices of refraction, the film may be formed of only two materials: half of the layers being of a first material giving these layers a first refractive index and the other half of the layers of a second material imparting a second refractive index to these layers, the change from a layer having the first refractive index and a layer having the second refractive index to the film imparting their interference properties.
    Although the film in the present case is composed of a stack of sheets having different refractive indices, the film may have any structure by which the film may be given interference properties. The film may thus comprise a network of microelements (such as microspheres) in three dimensions or a liquid crystal-based structure. In contrast to an OVI color or, more generally, a colored layer which contains particular pigments, it is above all the special internal structure of the film with interference effects, and not the material of which it is formed, which gives the film its optical properties.
    The film can be arranged partly in the thickness of the carrier or fixed only on the carrier. The film may thus be a type of stain attached to the carrier. The film can also be glued to one of the sides of the security document. The film can also completely laminate or encapsulate one side of the security document.
    The security element can not contain the mark carried by the film. Preferably, however, the film will bear a mark. Labeling the foil allows the security element to be additionally secured and makes the fraudulent reproduction of the security document more difficult. "Marking" is understood to mean any kind of shape, symbol, seal, alphanumeric mark, etc. intentionally applied to the film or incorporated into the film to confirm the authenticity of the film may carry a protective layer, such as a lacquer layer, to protect the marker and / or the security element.
    The label may be printed by a type of dye other than those described, such as a dye that is visible in the visible spectrum or that is visible only under infrared or ultraviolet light, or more generally, a dye that is irradiated with a wavelength range of is centered around a first wavelength, is visible, and is transparent when irradiated with a wavelength range centered around a second wavelength. The dye may also be a dye which has a different color depending on the illumination with which the marker is illuminated and / or the angle at which the marker is viewed, such as a dye which is a first color on ultraviolet illumination and a second color in infrared lighting. The dye may also be a dye referred to as an "anti-Stokes" dye, which in the field of security documents designates the dyes containing luminescent substances which react upon excitation illumination of given wavelength, the dyes having a re-emission wavelength If the label is formed of at least one luminescent dye, it may be capable of reemit in several different wavelengths if it is of a given wavelength or wavelength range For example, the dye may be such that it is completely transparent under the visible spectrum and that it will react in three different colors (one wavelength in
    Greens, one in red and one in blue) when stimulated by infrared radiation.
    The dye of the label can thus allow a local variation of the optical properties of the film of the security element. This then makes the fraudulent reproduction of the security element particularly difficult.
    Although in this case the mark is applied by printing, the mark can be replaced by any other possible method, such as. B. by (mechanical or thermal) embossing of the film or by metallizing and / or demetallizing the film applied to the film or introduced into the film. Remarkably, the embossing of the film also makes it possible to locally change the optical properties of the film, which makes the fraudulent reproduction of the security element particularly difficult.
    The mark may be different than just described. Thus, the marker may include a bar code, a logo, an image and / or an alphanumeric code. The marker may not be a precise thing, but may be identifiable only by its shape or size, for example.
    The security document can not contain a coating that has a structure that acts like a refraction grid. Of course, in other embodiments than described, the security document may include a cover having a structure that acts like a diffraction grating.
    The security document may not include an opening that allows viewing of the second side of the film integrated into the carrier or attached to the carrier.
    The described method of determination is of course applicable to embodiments other than those described.
    The determination method may include a different number of steps for illuminating and determining the light beam related variable than those described. The determination can be made only for the reflected light rays or only for the light rays transmitted by the security document and not simultaneously for the reflected rays and the rays transmitted by the security document. The illuminations according to different angles of incidence may also be wavelength ranges centered around different wavelengths.
    When the mark is printed from a dye which is visible upon irradiation with a wavelength region centered around a first wavelength, and is transparent upon irradiation with a wavelength region centered around a second wavelength the method comprising the steps of: illuminating a first side of the security document at a first angle of incidence having a wavelength range centered about a first wavelength, and determining at least one variable representative of a first light beam reflected from the security document and capturing at least one image of at least a portion of the security document, illuminating a first side of the security document at the second angle of incidence, and determining at least one variable representative of a second beam of light reflected from the security document, and Capturing at least a second image of at least a portion of the security document, - assessing the authenticity of the security document as a function of the particular variable, - determining the mark on the first image and the second image, - analyzing the authenticity of the mark based on the determination of the mark on the first Image and the second image, indicating whether the security document is genuine, depending on the step of assessing the authenticity of the security document in dependence on the determined variables and the step of verifying the authenticity of the marking.
    Thus, it proves possible to simultaneously determine the authenticity of the film and the mark carried by the film.
    Each radiation source may be operable according to a single mode of excitation other than that of the other radiation sources. In one embodiment, each radiation source may illuminate the security document under illuminations having wavelength ranges centered around different wavelengths. For the entire present application, the illumination of the banknote for carrying out the determination method will be such that the wavelength range of the illumination will always comprise at least part of the visible spectrum. Visible spectrum is, of course, the part of the electromagnetic spectrum that is visible to the human eye (which essentially corresponds to a wavelength range of 380-800 nanometers).
    In carrying out the method for determining the authenticity, a different number of answers can be determined. The answers can also be obtained only from a single particular viewing angle by illuminating the security element differently (different angle of illumination, different kind of light, illumination of the back of the security document and the front of the security document ...).
    Instead of illuminating one side of the security document and at the same time inspecting the rays transmitted and reflected by the security document from each side of the security document, one side of the security document can successively illuminate each page of the security document and successively transmit those from the security document on a single page of the security document and examine reflected rays.
    The radiation sources can be arranged opposite the two sides of the security document. The sensors may be arranged opposite a single side of the security document. The position and orientation of each of the sensors and each of the radiation sources shown in Figure 6 are of course not limiting.
    权利要求:
    Claims (21)
    [1]
    claim
    A security document comprising a support (2, 102, 202) comprising at least one security element (3, 103, 203), the document being characterized in that the security element is a translucent, colored film (4, 110, 210) includes interference effects.
    [2]
    A security document according to claim 1, wherein the security element comprises a marker (6, 111, 221) carried by the film (4, 110, 210).
    [3]
    The security document of claim 2, wherein the label comprises at least one fluorescent dye.
    [4]
    The security document of claim 3, wherein the fluorescent dye is capable of re-emitting in multiple wavelengths when excited at at least a given wavelength.
    [5]
    5. Security document according to claim 2, wherein the marking (6, 111, 221) by printing, metallizing and / or demetallizing, embossing on the film (4, 110, 220) applied or in the film (4, 110, 220) is introduced.
    [6]
    A security document according to claim 2, wherein the marker (4, 110, 220) comprises a bar code and / or logo and / or image and / or alphanumeric code.
    [7]
    A security document according to claim 1, wherein the film (4, 110, 220) is a multilayer film.
    [8]
    A security document according to claim 7, wherein each layer comprises a sheet, each sheet having a refractive index different from that of the two sheets which it frames.
    [9]
    A security document according to claim 1, wherein the film (4, 110, 210) has a thickness of less than 50 microns.
    [10]
    The security document of claim 1, wherein the foil comprises a mesh of microelements in three dimensions.
    [11]
    A security document according to claim 1, wherein the film (4, 110) is at least partially integrated in the thickness of the carrier.
    [12]
    The security document of claim 1, wherein the film (220) is mounted on the carrier.
    [13]
    The security document of claim 12, wherein the film is laminated to a whole side of the carrier or the film (220) is adhered to a portion of the carrier.
    [14]
    The security document of claim 1, further comprising a cover (115) having a structure that acts like a diffraction grating.
    [15]
    The security document of claim 14, wherein the cover (115) covers one side of the film (110).
    [16]
    The security document of claim 1, wherein the security element is configured to have an asymmetrical structure in a plane (P, P ') of the security element that is parallel to the two major sides of the security element and that extends in the center of the security element ,
    [17]
    A security document according to claims 8 and 16, wherein a first sequence of sheets and a second sequence of sheets are disposed on both sides of a central sheet, the first sheet sequence having refractive indices different from those of the second sheet sequence.
    [18]
    18. A method for determining the authenticity of a security document according to claim 1, comprising in succession the steps of: illuminating a first side of the security document (1, 101, 201) at a first angle of incidence with a wavelength range centered around a first wavelength and determining at least one variable representative of a first light beam reflected from the security document (1, 101, 201), illuminating the first side of the security document (1, 101, 201) at a second angle of incidence, which is is different from the first angle of incidence, and having a wavelength range centered around a second wavelength different from or identical to the first wavelength, and determining at least one variable representative of a second light beam derived from the first angle of incidence Security document (1, 101, 201) is reflected, - Evaluate the E the security document (1, 101, 201) as a function of the variables determined, - indicating whether the security document (1, 101, 201) is genuine or not.
    [19]
    A determination method according to claim 18, comprising the additional steps of determining at least one variable representative of a third light beam refracted and transmitted by the security document (1, 101, 201) when the first side is at the first angle of incidence and with a wavelength range centered around the first wavelength, and determining at least one variable representative of a fourth light beam that is refracted and transmitted by the security document (1, 101, 201) when the first one Page is illuminated at the second angle of incidence and with a wavelength range centered around the second wavelength, the step of evaluating the authenticity of the security document (1, 101, 201) then being performed in dependence on the variable representative of the first light beam, the second light beam, the third light beam and the fourth light beam are.
    [20]
    20. A device for carrying out the determination method according to claim 18 or claim 19, comprising at least a first radiation source (301) and a second radiation source (302) which are mutually spaced from the first side of the security document (1, 101, 201) and at least first means for determining variables representative of the rays reflected from the security document, the first determining means being located opposite the first side of the security document.
    [21]
    21. A detection device according to claim 20, further comprising at least second means for determining variables representative of light rays which are refracted and transmitted by the security document, the second determination means being arranged opposite the second side of the security document.
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    CH707981B1|2017-05-31|Diffractive device, and method and apparatus for viewing the same.
    DE112014004635T5|2016-09-15|Security document comprising a film with interference effects, method for determining the authenticity of such a document and apparatus for carrying out such a method
    DE212012000264U1|2014-11-05|Security document with a translucent IR, magnetic or fluorescent motif
    DE112015001463T5|2016-12-15|Volume holograms for security documents
    DE102010051087A1|2012-05-16|Method and device for checking the authenticity of banknotes with security windows
    DE102017102556A1|2018-08-09|A method for verifying a security document and a security document, a device and a security element
    RU2561413C1|2015-08-27|Multi-layer composite element based on paper and valuable counterfeit-proof document
    EP3415339A1|2018-12-19|Method for the unique identifying of a document and security or value document
    DE102019006315A1|2021-03-11|Optically variable security element
    DE102019129491A1|2021-05-06|Examination of a security document based on droplet morphologies
    DE112019004255T5|2021-05-06|Security documents and security devices comprising infrared absorbing compositions
    同族专利:
    公开号 | 公开日
    FR3011508A1|2015-04-10|
    DE112014004635T5|2016-09-15|
    AT517776B1|2021-12-15|
    WO2015052181A1|2015-04-16|
    AT517776A5|2021-09-15|
    FR3011508B1|2021-05-28|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    CA2238384C|1995-11-28|2007-01-16|Electrowatt Technology Innovation Ag|Optical information carrier|
    KR20040041696A|2001-10-19|2004-05-17|레오나르트 쿠르츠 게엠베하 운트 코. 카게|Embossed film and security document|
    US6970236B1|2002-08-19|2005-11-29|Jds Uniphase Corporation|Methods and systems for verification of interference devices|
    DE102008029158A1|2007-12-21|2009-06-25|Giesecke & Devrient Gmbh|security element|
    DE102009031877A1|2008-12-23|2010-07-01|Giesecke & Devrient Gmbh|Security element with improved heat-seal adhesive|
    US20120094038A1|2010-10-13|2012-04-19|Honeywell International Inc.|Use of humidity stable yellow fluorescent pigments in security applications|
    US20130048874A1|2011-08-31|2013-02-28|Honeywell International Inc.|Articles with confounded emission characteristics and methods and apparatus for their authentication|
    GB201203183D0|2012-02-24|2012-04-11|Qinetiq Ltd|Optical multilayer|FR3059810B1|2016-12-02|2018-11-23|Banque De France|REPOSITIONING AN IMAGE ON THE SCREEN OF AN APPARATUS|
    FR3059594B1|2016-12-02|2021-05-28|Banque De France|TWO SAFETY SIGNS JOINTLY FORMING A THIRD SAFETY SIGN|
    FR3078801A1|2018-03-08|2019-09-13|Cypheme|METHOD FOR DETERMINING THE AUTHENTICITY OF A DOCUMENT AND DEVICE FOR IMPLEMENTING SUCH A METHOD|
    法律状态:
    优先权:
    申请号 | 申请日 | 专利标题
    FR1359745A|FR3011508B1|2013-10-08|2013-10-08|SECURITY DOCUMENT INCLUDING A FILM WITH INTERFERENTIAL EFFECTS, PROCESS FOR DETERMINING THE AUTHENTICITY OF SUCH A DOCUMENT AND DEVICE FOR IMPLEMENTING SUCH A PROCESS.|
    PCT/EP2014/071434|WO2015052181A1|2013-10-08|2014-10-07|A security document comprising a film with interferential effects, a method for determining the authenticity of such a document and a device for implementing such a method|
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