EP1276079A1 - Method and apparatus for authenticating a security document by means of multifrequency analysis - Google Patents

Abstract

A banknote (1) has a watermarked security sign (100) in the middle and is placed such that the watermark receives two beams of light (E1,E2) which are transmitted at different wavelengths ( lambda 1, lambda 2). A beam (T) emerges from the other side of the banknote and is captured by a light sensor (R). The incident beams may be coincident in time or alternately intermittent, in either case comparison is made with reference responses An Independent claim is also included for: Equipment to project two beams of different wavelengths.

Description

• l'exposition du signe de sécurité à filigrane à un rayonnement d'authentification,
• le recueil de la réponse du signe de sécurité à filigrane audit rayonnement d'authentification, et
• la comparaison de ladite réponse avec une réponse de référence afin d'authentifier le document

The present invention relates to a method for authenticating a security document comprising a watermark security sign, the method comprising:

• exposure of the watermarked security sign to authentication radiation,
• collecting the response of the watermark security sign to said authentication radiation, and
• comparison of said response with a reference response in order to authenticate the document

The invention also relates to a device for implementing of such a process.

It is known to integrate security documents such as watermark bank notes. Such an arrangement makes it possible to secure the document, the watermark being visually recognizable.

The watermark can be recognized with the naked eye by a observer.

It is also possible to have an invisible watermark recognized by the naked eye by a machine adapted for this purpose, provided with a light source as well as at least one optical sensor for collecting the response characteristic of the watermark to the light radiation emitted by the source.

More specifically, in the case of authentication machines automatic, the light source generally emits radiation whose wavelength spectrum is centered on a value of the spectrum infrared.

The optical sensor then collects the response from the document area containing the watermark, also in the infrared spectrum, which allows lessen the influence of the other visual elements of the document which are visible in natural light (and often chosen invisible in infrared light).

Comparing the response of the documents to a response of reference stored in the authentication machine then allows to authenticate the document.

The advantage of such an automatic authentication machine to authenticate a document extremely quickly, and can process a large number of documents in a short space of time.

But moreover, the increasingly sophisticated means including feature the counterfeiters allow them to associate with documents fraudulent markings that are likely to reproduce the answer characteristic of a radiation watermark of the type mentioned above.

We specify that we also know many other types of means to secure documents. We can for example cite the document EP 1,065,631 which teaches a method and a device for reading recording media in the form of sheets. But such lessons do not concern the authentication of a security document with a watermark.

There thus appears a need to increase the level of security of authentication of documents with a watermark.

The object of the invention is to meet this need.

• l'exposition du signe de sécurité à filigrane à un rayonnement d'authentification,
• le recueil de la réponse du signe de sécurité à filigrane audit rayonnement d'authentification, et
• la comparaison de ladite réponse avec une réponse de référence afin d'authentifier le document,

   caractérisé en ce que ledit rayonnement d'authentification comprend au moins deux rayonnements élémentaires, les caractéristiques spectrales de chaque rayonnement élémentaire étant différentes, et la réponse de référence prend en compte une réponse attendue du document à au moins un rayonnement élémentaire.In order to achieve this aim, the invention proposes, according to a first aspect, a method of authenticating a security document comprising a watermarked security sign (100), the method comprising:

• exposure of the watermarked security sign to authentication radiation,
• collecting the response of the watermark security sign to said authentication radiation, and
• comparing said response with a reference response in order to authenticate the document,

characterized in that said authentication radiation comprises at least two elementary radiations, the spectral characteristics of each elementary radiation being different, and the reference response takes into account an expected response of the document to at least one elementary radiation.

• la réponse de référence correspond à une relation prédéterminée entre les réponses du signe de sécurité à filigrane à chaque rayonnement élémentaire,
• ladite relation prédéterminée est un différentiel entre les réponses du signe de sécurité à filigrane à deux rayonnements élémentaires,
• lors de l'exposition du signe de sécurité à un rayonnement d'authentification, le signe de sécurité reçoit en même temps les rayonnements élémentaires,
• chaque rayonnement élémentaire est centré autour d'une longueur d'onde différente,
• lesdites longueurs d'onde sont des longueurs d'onde infrarouges,
• lesdites longueurs d'onde comprennent respectivement une longueur d'onde de l'ordre de 880nm et de l'ordre de 1500nm,
• lesdites longueurs d'onde comprennent respectivement une longueur d'onde de l'ordre de 880nm et de l'ordre de 2µm,
• le rayonnement d'authentification est composé d'une séquence d'impulsions respectives d'un des rayonnements élémentaires,
• lors de chaque impulsion un seul rayonnement élémentaire est émis,
• les réponses du signe de sécurité à filigrane sont recueillies en transmission au travers du document,
• le procédé comprend le recueil de la réponse de différentes régions du document qui sont imprimées par différentes encres de sécurité respectives, afin de recueillir pour chaque région une réponse spécifique à une excitation lumineuse selon chacune des longueurs d'onde respectives utilisées pour illuminer le document par les rayonnements élémentaires,
• on fait défiler le document dans une direction déterminée, en lisant simultanément deux réseaux superposés, avec un premier réseau qui est filigrané périodique, et dont l'onde s'étend dans une direction commune essentiellement non perpendiculaire et non parallèle à la direction de défilement, et avec un second réseau organisé en bandes selon un codage binaire, lesdites bandes s'étendant parallèlement à la direction de défilement, et étant codées perpendiculairement à ladite direction de défilement, symétriquement de part et d'autre de l'axe du document qui est parallèle à ladite direction de défilement, et lesdites bandes présentant une même largeur de bande donnée par la formule e = P2 sin β , où P est la longueur d'onde du premier réseau et β l'angle entre ladite direction commune et ladite direction de défilement,
• on dispose des moyens de détection à raison d'au moins un par bande du second réseau, ces moyens étant organisés selon une direction générale perpendiculaire à la direction de défilement, avec une interdistance égale à la largeur des bandes parallèles dudit second réseau,
• on vérifie le codage du second réseau en additionnant la réponse de chaque bande et de sa symétrique qui lui est conjuguée, afin d'éliminer l'influence du premier réseau, et en comparant les résultats obtenus aux valeurs théoriques de codage,
• on analyse le premier réseau par soustraction des réponses de chaque bande exempte de codage et de sa symétrique,
• les moyens de détection sont situés sur l'axe médian des bandes associées du second réseau,
• le document défilant dans une direction déterminée, on lit simultanément deux réseaux superposés, avec un premier réseau qui est filigrané périodique, et dont l'onde s'étend dans une direction commune essentiellement parallèle à la direction de défilement, et avec un second réseau qui est organisé en bandes selon un codage binaire, lesdites bandes s'étendant parallèlement à la direction de défilement, et étant codées perpendiculairement à ladite direction de défilement, symétriquement de part et d'autre de l'axe du document qui est parallèle à ladite direction de défilement, et lesdites bandes présentant une même largeur de bande sensiblement égale à la demi-longueur d'onde du premier réseau, et le procédé comporte les étapes suivantes :
• 
  on dispose des moyens de détection à raison d'au moins un par bande du second réseau, ces moyens étant organisés selon une direction générale perpendiculaire à la direction de défilement et situés sur l'axe médian des bandes associées, avec, d'un côté dudit axe du document des premiers moyens de détection alignés entre eux, et, de l'autre côté dudit axe, des seconds moyens de détection également alignés entre eux mais décalés des premiers moyens de détection d'une distance (d 1) sensiblement égale à la demi-longueur d'onde du premier réseau,
• on vérifie le codage du second réseau en additionnant la réponse de chaque bande et de sa symétrique qui lui est conjuguée, afin d'éliminer l'influence du premier réseau, et en comparant les résultats obtenus aux valeurs théoriques de codage,
• on analyse le premier réseau par soustraction des réponses de chaque bande exempte de codage et de sa symétrique.

Preferred, but non-limiting aspects of the process according to the invention are the following:

• the reference response corresponds to a predetermined relationship between the responses of the watermark security sign to each elementary radiation,
• said predetermined relationship is a differential between the responses of the watermark security sign to two elementary radiations,
• when the security sign is exposed to authentication radiation, the security sign receives elementary radiation at the same time,
• each elementary radiation is centered around a different wavelength,
• said wavelengths are infrared wavelengths,
• said wavelengths respectively comprise a wavelength of the order of 880nm and of the order of 1500nm,
• said wavelengths respectively comprise a wavelength of around 880nm and around 2µm,
• the authentication radiation is composed of a sequence of respective pulses of one of the elementary radiations,
• during each pulse only one elementary radiation is emitted,
• the responses of the watermark security sign are collected by transmission through the document,
• the method comprises collecting the response from different regions of the document which are printed by different respective security inks, in order to collect for each region a specific response to light excitation according to each of the respective wavelengths used to illuminate the document by elementary radiation,
• the document is scrolled in a determined direction, by simultaneously reading two superimposed networks, with a first network which is watermarked periodically, and whose wave extends in a common direction essentially non-perpendicular and not parallel to the direction of scrolling, and with a second network organized in bands according to a binary coding, said bands extending parallel to the direction of travel, and being encoded perpendicular to said direction of travel, symmetrically on either side of the axis of the document which is parallel to said direction of travel, and said bands having the same bandwidth given by the formula e = P 2 sin β , where P is the wavelength of the first grating and β the angle between said common direction and said running direction,
• detection means are available at the rate of at least one per strip of the second network, these means being organized in a general direction perpendicular to the direction of travel, with a distance equal to the width of the parallel strips of said second network,
• the coding of the second network is checked by adding the response of each band and its symmetric which is conjugate to it, in order to eliminate the influence of the first network, and by comparing the results obtained with the theoretical coding values,
• the first network is analyzed by subtracting the responses from each codeless band and its symmetric,
• the detection means are located on the median axis of the associated bands of the second network,
• the document scrolling in a determined direction, two superimposed networks are simultaneously read, with a first network which is watermarked periodically, and whose wave extends in a common direction essentially parallel to the direction of scrolling, and with a second network which is organized into bands according to a binary coding, said bands extending parallel to the direction of travel, and being coded perpendicular to said direction of travel, symmetrically on either side of the axis of the document which is parallel to said direction scrolling, and said bands having the same bandwidth substantially equal to the half-wavelength of the first network, and the method comprises the following steps:
• 
  detection means are available at the rate of at least one per strip of the second network, these means being organized in a general direction perpendicular to the direction of travel and located on the median axis of the associated strips, with, on one side of said document axis of the first detection means aligned with each other, and, on the other side of said axis, of the second detection means also aligned with each other but offset from the first detection means by a distance (d 1) substantially equal to the half-wavelength of the first network,
• the coding of the second network is checked by adding the response of each band and its symmetric which is conjugate to it, in order to eliminate the influence of the first network, and by comparing the results obtained with the theoretical coding values,
• the first network is analyzed by subtracting the responses from each codeless band and its symmetric.

According to a second aspect, the invention also proposes a device for implementing a method as mentioned above, characterized by the fact that it includes means for emitting a authentication radiation around at least two wavelengths different.

• lesdits moyens comprennent deux sources de lumière qui émettent autour de longueurs d'onde différentes,
• les sources sont confondues en une seule source,
• le dispositif comprend un récepteur apte à recueillir les réponses du document aux excitations autour des rayonnements élémentaires respectifs, et des moyens de comparaison de ces réponses à des réponses de référence mémorisées dans le dispositif,
• le dispositif comporte une première source apte à émettre autour de 880nm, et une deuxième source apte à émettre autour de 1500nm ou de 2µm,
• la réponse de référence correspond à une relation prédéterminée entre les réponses du signe de sécurité à filigrane à chaque rayonnement élémentaire,
• des moyens amplificateurs sont prévus entre les capteurs et les moyens sommateurs ou différentiateurs associés,
• la barrette de lecture présente des ouvertures sensiblement circulaires équidistantes associées à chaque capteur,
• la barrette de lecture présente des ouvertures en forme de fentes associées à chaque capteur, chaque fente étant inclinée de façon à être sensiblement perpendiculaire à la direction de propagation de l'onde du premier réseau du document,
• la barrette de lecture présente des ouvertures cruciformes associées à chaque capteur, les deux branches de chaque ouverture étant inclinées de façon à être sensiblement parallèle et perpendiculaire à la direction de propagation de l'onde du premier réseau du document,
• l'un au moins des capteurs est multiple,
• le capteur multiple est constitué par deux capteurs adjacents disposés de part et d'autre de l'axe médian de chaque bande du second réseau du document,
• le capteur multiple est constitué par quatre capteurs disposés en carré, les bords du carré étant parallèles et perpendiculaires à la direction de défilement,
• les capteurs sont aptes à recueillir la réponse du document à chaque rayonnement élémentaire,
• les capteurs uniques ou multiples sont des photo-diodes, ou des photo-transistors, ou des cellules photo-résistantes, chacun desdits capteurs étant associé à des filtres optiques pour se caler à la longueur d'onde désirée,
• les capteurs de la barrette sont organisés pour présenter un même gain et un même calage d'origine, de façon à assurer l'équilibrage des différentes voies,
• la barrette de lecture comporte une rangée de capteurs agencée perpendiculairement à la direction de défilement, lesdits capteurs étant équidistants entre eux d'une distance sensiblement égale à la largeur des bandes parallèles du second réseau du document à analyser,
• la barrette de lecture comporte deux rangées parallèles de capteurs agencées perpendiculairement à la direction de défilement, lesdites rangées étant décalées entre elles d'une distance prédéterminée sensiblement égale à la demi-longueur d'onde du premier réseau du document à analyser, et les capteurs d'une même rangée étant équidistants entre eux d'une distance sensiblement égale à la largeur des bandes parallèles du second réseau dudit document.

Preferred but non-limiting aspects of the device according to the invention are the following:

• said means comprise two light sources which emit around different wavelengths,
• sources are merged into a single source,
• the device comprises a receiver capable of collecting the responses of the document to the excitations around the respective elementary radiations, and means for comparing these responses with reference responses stored in the device,
• the device comprises a first source capable of emitting around 880 nm, and a second source capable of emitting around 1500 nm or 2 μm,
• the reference response corresponds to a predetermined relationship between the responses of the watermark security sign to each elementary radiation,
• amplifying means are provided between the sensors and the associated summing or differentiating means,
• the reading strip has substantially circular equidistant openings associated with each sensor,
• the reading strip has slots-shaped openings associated with each sensor, each slot being inclined so as to be substantially perpendicular to the direction of propagation of the wave of the first grating of the document,
• the reading strip has cruciform openings associated with each sensor, the two branches of each opening being inclined so as to be substantially parallel and perpendicular to the direction of propagation of the wave of the first grating of the document,
• at least one of the sensors is multiple,
• the multiple sensor is constituted by two adjacent sensors arranged on either side of the median axis of each strip of the second network of the document,
• the multiple sensor is made up of four sensors arranged in a square, the edges of the square being parallel and perpendicular to the direction of travel,
• the sensors are capable of collecting the response of the document to each elementary radiation,
• the single or multiple sensors are photo-diodes, or photo-transistors, or photo-resistive cells, each of said sensors being associated with optical filters to calibrate at the desired wavelength,
• the sensors of the bar are organized to present the same gain and the same original setting, so as to balance the different channels,
• the reading strip comprises a row of sensors arranged perpendicular to the direction of travel, said sensors being equidistant from each other by a distance substantially equal to the width of the parallel strips of the second network of the document to be analyzed,
• the reading strip has two parallel rows of sensors arranged perpendicular to the direction of travel, said rows being offset from each other by a predetermined distance substantially equal to the half-wavelength of the first grating of the document to be analyzed, and the sensors of the same row being equidistant from each other by a distance substantially equal to the width of the parallel strips of the second network of said document.

• la figure 1 est un schéma de principe illustrant le principe général de l'invention,
• les figures 2 à 17 illustrent un mode particulier et non limitatif de mise en oeuvre de l'invention, dans lequel un document de sécurité présente la particularité de comporter un deuxième signe de sécurité en addition d'un premier signe de sécurité constitué à base d'un réseau de filigrane. Plus précisément, sur ces figures :
• la figure 2 illustre un document rectangulaire destiné à être analysé par un procédé et un dispositif conformes à l'invention, document dont des premier et second signes de sécurité ont été représentés en pointillés, ces signes étant superposés,
• la figure 3 est une vue en plan illustrant le premier signe de sécurité du document précité, qui est réalisé sous la forme d'un réseau périodique filigrané organisé ici selon un carré, tel qu'il peut se voir par transparence, avec une alternance de zones claires et opaques correspondant aux variations de la masse surfacique dans cette zone filigranée,
• la figure 4 illustre en plan la face en relief d'une matrice permettant d'emboutir la toile formaire lors de la fabrication du document, pour obtenir un réseau périodique filigrané analogue à celui de la figure 3, les ondulations, ici sinusoïdales, de cette face en relief permettant de réaliser les variations désirées de la masse surfacique dans cette zone filigranée, les bords de cette matrice étant en outre ici biseautés pour adoucir les contrastes au niveau des bords de ladite zone,
• les figures 5 à 9 sont des coupes, respectivement selon V-V, VI-VI, VII-VII, VIII-VIII et IX-IX de la figure 4, permettant de mieux comprendre l'organisation de la face en relief de la matrice, et en particulier de ses bords biseautés, par rapport au plan moyen de ladite face,
• les figures 5a à 9a sont des courbes illustrant les variations de la masse surfacique de la zone filigranée obtenue avec la matrice précitée, ces courbes correspondant respectivement aux coupes des figures 5 à 9 (les courbes de variations de la masse surfacique dans le papier sont en effet des transformées directes des courbes correspondantes des variations du relief de la face de la matrice d'emboutissage),
• les figures 10 et 11 illustrent le document de la figure 2, avec deux codages différents des bandes parallèles du second réseau, tel que ce document apparaít par exemple lorsqu'il est examiné sous infrarouge (pour un graphisme imprimé avec un couple d'encres dont l'une absorbe l'infrarouge et l'autre pas), avec ici huit parallèles respectivement codées 10111101 et 01100110,
• la figure 12 est une vue en transparence du réseau périodique filigrané obtenu avec la matrice précédemment illustrée, avec un contour carré à bords biseautés, et avec un déphasage particulier par rapport aux axes du carré (qui sont de préférence confondus avec les deux axes de symétrie du document rectangulaire,
• la figure 13 est une vue à plus grande échelle, montrant une zone du document où les deux signes de sécurité sont superposés (il y a ici six bandes parallèles du second réseau, qui traversent la zone filigranée avec le premier réseau périodique), cette vue permettant de comprendre comment les deux réseaux superposés sont agencés pour une imbrication compatible avec une analyse par un organe unique au niveau duquel défile le document,
• la figure 14 complète la vue précédente en montrant une barrette de capteurs conforme à l'invention, permettant l'analyse du document précité, avec un capteur pour chaque bande parallèle du second réseau, ladite barrette étant disposée perpendiculairement à la direction de défilement du document,
• la figure 15 illustre une variante de l'invention dans laquelle la direction (DC) de propagation de l'onde du réseau filigrané n'est pas comme précédemment inclinée à 45° par rapport à la direction de défilement (DD), mais est parallèle à ladite direction de défilement, la barrette de capteurs conforme à l'invention étant dans ce cas agencée différemment, avec deux rangées de capteurs décalées comme cela est visible sur la figure,
• les figures 16a à 16d sont des vues partielles illustrant différentes variantes d'agencement des capteurs de la barrette de la figure 14, avec respectivement des ouvertures en fentes inclinées, des ouvertures cruciformes, des capteurs multiples à deux capteurs adjacents, et des capteurs multiples à quatre capteurs disposés en carré,
• la figure 17 est un schéma d'un dispositif d'analyse conforme à l'invention, associé ici à la barrette de capteurs de la figure 14, montrant le traitement des signaux provenant des différents capteurs, afin d'une part de vérifier le codage du second réseau et de valider le document analysé lorsque le second réseau est conforme, et d'autre part d'analyser le premier réseau et de valider le document analysé lorsque le premier réseau est conforme.

Other aspects, aims and advantages of the invention will appear better on reading the following description of an embodiment of the method according to the invention, referring to the appended drawings in which:

• FIG. 1 is a block diagram illustrating the general principle of the invention,
• Figures 2 to 17 illustrate a particular and non-limiting mode of implementation of the invention, in which a security document has the distinction of having a second security sign in addition to a first security sign based on d 'a watermark network. More specifically, in these figures:
• FIG. 2 illustrates a rectangular document intended to be analyzed by a method and a device in accordance with the invention, document of which first and second safety signs have been shown in dotted lines, these signs being superimposed,
• Figure 3 is a plan view illustrating the first security sign of the aforementioned document, which is produced in the form of a watermarked periodic network organized here according to a square, as it can be seen by transparency, with an alternation of clear and opaque zones corresponding to variations in the surface mass in this watermarked zone,
• FIG. 4 illustrates in plan the relief face of a matrix making it possible to stamp the form cloth during the production of the document, in order to obtain a watermarked periodic network similar to that of FIG. 3, the undulations, here sinusoidal, of this embossed face allowing the desired variations in the surface mass to be produced in this watermarked zone, the edges of this matrix also being bevelled here to soften the contrasts at the edges of said zone,
• FIGS. 5 to 9 are sections, respectively along VV, VI-VI, VII-VII, VIII-VIII and IX-IX of FIG. 4, allowing a better understanding of the organization of the raised face of the matrix, and in particular of its bevelled edges, relative to the mean plane of said face,
• FIGS. 5a to 9a are curves illustrating the variations in the surface mass of the watermarked zone obtained with the above-mentioned matrix, these curves corresponding respectively to the sections of FIGS. 5 to 9 (the curves of variations in the surface mass in the paper are in effect of direct transforms of the corresponding curves of the variations in the relief of the face of the stamping matrix),
• Figures 10 and 11 illustrate the document of Figure 2, with two different codings of the parallel bands of the second network, as this document appears for example when examined under infrared (for a graphic printed with a couple of inks including one absorbs infrared and the other does not), here with eight parallels respectively coded 10111101 and 01100110,
• FIG. 12 is a view in transparency of the watermarked periodic network obtained with the matrix previously illustrated, with a square contour with bevelled edges, and with a particular phase shift relative to the axes of the square (which are preferably coincident with the two axes of symmetry of the rectangular document,
• Figure 13 is an enlarged view showing an area of the document where the two security signs are superimposed (here there are six parallel bands of the second network, which cross the watermarked zone with the first periodic network), this view allowing to understand how the two superimposed networks are arranged for a nesting compatible with an analysis by a single organ at the level of which the document scrolls,
• FIG. 14 completes the previous view by showing a sensor strip according to the invention, allowing the analysis of the aforementioned document, with a sensor for each parallel strip of the second network, said strip being arranged perpendicular to the direction of travel of the document ,
• FIG. 15 illustrates a variant of the invention in which the direction (DC) of propagation of the wave of the watermarked network is not as previously inclined at 45 ° with respect to the direction of travel (DD), but is parallel in said direction of travel, the sensor strip according to the invention being in this case arranged differently, with two rows of sensors offset as shown in the figure,
• FIGS. 16a to 16d are partial views illustrating different variant arrangements of the sensors of the bar of FIG. 14, with respectively apertures in inclined slots, cruciform openings, multiple sensors with two adjacent sensors, and multiple sensors with four sensors arranged in a square,
• FIG. 17 is a diagram of an analysis device according to the invention, associated here with the array of sensors of FIG. 14, showing the processing of the signals coming from the various sensors, in order on the one hand to verify the coding of the second network and of validating the document analyzed when the second network is in conformity, and on the other hand of analyzing the first network and of validating the document analyzed when the first network is in conformity.

Referring first to Figure 1, there is shown in section longitudinal security document such as a banknote 1.

Ticket 1 has a security sign in its middle region 100, which includes at least one watermark.

Figure 1 shows the general principle of document authentication according to the invention: according to this principle, the ticket 1 is placed so that the safety sign 100 receives light radiation from two sources of light E1 and E2, which emit around respective wavelengths λ1 and λ2 (λ1 and λ2 being different).

The safety sign 100 thus illuminated by these two radiations of different wavelengths transmits on the other side of the ticket a transmitted radiation T which is picked up by a light receiver R.

Collecting the security sign response to two radiation of different wavelengths increases significantly the security level of authentication.

Indeed, fraudulent markings which seek to imitate the response of safety sign 100 to wavelength radiation given could not in any case also imitate the answer of said sign with two excitations according to two different wavelengths λ1 and λ2.

Thus according to the invention, the responses of the ticket are collected (and more particularly in the region with watermark security sign 100) to the two excitations around λ1 and λ2 respectively, and we compare these responses to reference responses stored in the device authentication.

It is specified that the illumination of the security sign 100 by the radiation centered on the respective lengths λ1 and λ2 can be done continuously, the safety sign in this case receiving at the same time the two radiations at the same time.

In this case, the response collected corresponds to a transmitted signal T in which the individual responses of the security sign are superimposed 100 to each of the two excitation rays.

The adapted processing means then separate the two components of the signal T, in order to isolate each individual response from the sign safety to each of the two respective excitation radiations.

It is also possible to predict that the security sign will be successively exposed to impulses from each of these two respective radiations according to any desired time sequence.

In this case, the light response transmitted by the ticket must present the two expected individual responses to the two excitations respective, respecting the corresponding time sequence.

Of course the two sources E1 and E2 can be confused with only one source.

Likewise, the receiver R can be a single device, or be consisting of two respective receivers (or sets of receivers respectively), each dedicated to receiving the radiation transmitted in response to illumination by one of the two wavelengths (in the case where the two radiations are not directed simultaneously towards the sign of security 100).

Each radiation centered around a wavelength λ1, λ2 thus constitutes an elementary radiation, the sum of the radiations elements constituting the authentication radiation according to the invention.

Collecting radiation from safety sign 100 by transmission is also not imperative; it is also possible according to the invention of collecting the light response of this safety sign by reflection. In this case, the receiver (s) is (will) be disposed of same side of the ticket as the light sources E1 and E2.

It is also possible according to the invention to provide to illuminate the ticket with a number of different elementary radiations which is greater than two, each radiation being centered around a length of different respective wave.

We can thus consider lighting the ticket with three (or more) radiation of different respective wavelengths, and to collect the response (in transmission and / or in reflection, the mode of response can also be adapted individually for each of the wavelengths of each elementary radiation).

In all cases, it will be checked that the respective responses of the document with different illuminations are consistent with responses from reference expected from this watermark security sign.

In one embodiment of the invention, two could be used different wavelengths, the first radiation being for example centered around a wavelength λ1 of 880nm and the second radiation being centered around a wavelength λ2 of 1,500nm.

According to a variant of the invention, it is also possible to provide that λ1 has a value of the order of 880nm and λ2 of the order of 2 µm.

The wavelengths mentioned above are particularly good suitable for high security authentication of security sign to watermark, to the extent that they effectively outwit lures that constitute known imitations of watermarks.

It is also possible according to the invention to authenticate a document security based on any predetermined relationship between responses expected from security sign 100 to the respective radiations of different wavelengths.

For example, in the case of the exposure of a security document to two lengths λ1 and λ2, authentication can be based on the fact that the responses (transmitted and / or reflected) to these two radiations satisfy any predetermined relationship.

An example is a simple differential measurement between the two responses, the difference between the two responses must then have a predetermined expected value stored in the device authentication, so that we can conclude that the authenticity of the document.

Indeed, a characteristic of the "real" watermarks is that their relative response varies little as a function of the illumination wavelength, while the means can be implemented by counterfeiters exhibit significantly different responses to illuminations of different wavelengths.

So if the value of the difference between the individual responses to two elementary wavelengths is within a range predetermined, it will be possible to deduce that the document to be authenticated is authentic.

For example, if the differential remains below a given value, we may conclude that the document is authentic. If this differential exceeds said value given, it is an imitation.

It is specified that in general, the reference response stored in the authentication devices and to which will compared the response of the ticket can take into account only one expected response of the document to elementary radiation, the ticket responses to other elementary radiation not being analyzed.

In a more sophisticated variant of the invention, plan to effectively use two or more responses from the document to the different elementary radiations, the reference response corresponding to a predetermined relationship between the responses of the safety sign with watermark on each elementary radiation.

It is also possible to collect the document's responses to different illuminations according to the elementary radiations which constitute the authentication scope, and check for each elementary radiation that the answer of the document corresponds to a expected response, without checking the relationship between these different responses.

In this case, the reference response is actually constituted by all the expected responses to the different radiations elementary.

It is also possible to further enhance the security of the document, additionally printing certain regions of the document by different respective security inks.

Each respective ink can thus present a specific response to a light excitation according to each of the respective wavelengths used to illuminate the document with elementary radiation.

Thus, we can illuminate the document by a predetermined sequence of light pulses of respective wavelengths λ1 and λ2, each region inked with a respective ink absorbing or not absorbing the radiation of each pulse, the inks associated with the different regions selectively absorbing some of the different radiations elementary.

In this way, for each pulse of illumination by radiation elementary, each region will be selectively visible (the ink associated with the region does not absorb radiation), or dark (ink absorbs radiation).

And we specify that it is also possible to make each region more or less visible under illumination by elementary radiation, the ink associated with each region can be more or less absorbent for the wavelength of said elementary radiation.

It is thus possible to carry out an analog coding in “gray levels” on the different regions of the ticket, said coding being able to be memorized in the identification device.

We will now describe in detail a non-limiting form of particular embodiment of the invention, in which a ticket 1 comprises no only a first security sign 100 comprising at least one watermark, but also a second security sign 200. This description of the particular embodiment will be made with reference to Figures 2 to 17.

Figure 2 illustrates the ticket 1, here rectangular, whose large edge is noted 2 and the small edge is noted 3.

This note presents on one side (front or back) a graphic print G, illustrating here a hang glider. A graphic can naturally be also provided on the other side of ticket 1.

Document 1 has, as we said, two security signs superimposed 100, 200, shown here in dotted lines.

The first security sign 100 is in the form of a periodic watermarked network, delimited by a closed contour C which is inside at edges 2, 3 of ticket 1. This first security sign is therefore visible by transparency, and then presents a succession of bands 101, 102 which are alternately darker and lighter. The appearance of these bands 101, 102 results from variations in the basis weight in this area watermark.

The second safety sign 200 is also produced in the form of a network, but this second sign results from a cutting of the graphics printed G in parallel strips 201, 202 which are coded.

The bands 201, 202 preferably arranged symmetrically by relation to an axis of symmetry of the ticket 1, in this case the axis X'X, which is parallel to the large edge 2 of said ticket 1.

There is therefore an even number of bands, arranged on either side of the X'X axis. The other axis of ticket 1 is denoted Y'Y in FIG. 1.

The direction of bands 201, 202 is denoted DD, and it will be seen that this direction coincides with the direction of travel of the ticket 1 when it it is a question of analyzing and authenticating said ticket 1.

The bands 201, 202 need not relate to the whole of ticket 1: in FIG. 2, two zones are therefore distinguished affected by ZL coding. In the particular case of a bank note, these two ZL zones can be used for numbering.

These bands 201, 202 are further coded according to binary coding. (0 or 1), and symmetrically with respect to the axis of symmetry X'X of ticket 1. The coding of the bands 201, 202 is thus organized along the axis Y'Y.

It is therefore interesting that the graphic G of ticket 1 is printed with several inks having the same shade under light illumination natural, some of which absorbent (more or less, as has been mentioned with regard to "analog coding") and others not, the radiation of one of the respective wavelengths λ1, λ2, ..., λn which are implemented by the different elementary radiations for the discrimination of watermarks of security sign 100.

More precisely, we will achieve this impression of the G graphics with several different inks so that part of the graphics being in each of the individual strips 201, 202 of the ticket be printed with a respective ink, all these inks having the same shade under natural light.

In this way, we define a division of the graphics G into strips parallel.

Taking for the rest of this description the simplified case in which the ticket is illuminated with a single wavelength λi (corresponding to the wavelength of only one of the elementary radiations used in the method according to the invention), when the design of the ticket 1 is printed with inks some of which absorb said radiation infrared and others not, examining ticket 1 under this radiation infrared corresponds to an image of the type illustrated in FIGS. 10 and 11.

The graphic G thus defines a binary coding.

It should be noted in this regard that we are assuming the detection of the response of the different regions of the pattern G in transmission.

However, this detection is, as has also been said, possible in reflection, any combination of detection in transmission / reflection being possible between responses to different elementary radiations received by the watermark sign 100 as well as by the sign 200.

We will detail below the principle for coding the second safety sign 200, for one-length illumination wave.

The implementation of this principle in the general context of the invention will involve the illumination of the ticket by different wavelengths different (at least two).

In FIG. 10, there is thus successively a strip 202 coded 1 (absorbs wavelength λi, so lets see in dark color the concerned part of the graphic as well as the concerned zone of the first watermarked network 100), a band 201 coded 0 (does not absorb the length wave λi, so hides the graphics, leaving only the concerned zone of the first watermarked network 100), then two bands 202 coded 1.

It is specified that the inks being generally transparent and the semi-reflective infrared paper, absorbent ink will be seen darker both in reflection and in transmission.

The use of such ink for coding the second network is then represented by a code 1, while the non-absorbent ink (and therefore invisible in infrared light) will be symbolized by a 0.

Here again, the inks used for printing the bands 201 and 202 can be more or less absorbent for λi, so as to create a "Analog coding".

The symmetry of the coding with respect to the X'X axis then implies the successively presence of two bands 202, of a band 201, and finally of a strip 202.

The binary coding illustrated in FIG. 10 is therefore 10111101.

FIG. 11 illustrates another coding with the same number of parallel bands: the coding is then 01100110 (the symmetry of the coding with respect to the X'X axis is naturally always respected).

In FIGS. 10 and 11, eight parallel bands are provided, so that there are in fact 2 ⁴ , ie 16 different codings.

More generally, with 2n bands coded 0 or 1, there will be 2 ⁿ different codings.

In the particular case where the responses of bands 201, 202 are collected in reflection, the coding by cutting of the printed graphics may relate to the front, back, or both.

In the latter case, reading ticket 1 will be easier if you use the same coding on the front and back, the corresponding bands being thus directly superimposed; this possibility can be interesting in to the extent that it allows better resistance to aging.

In practice, a sufficient number of bands will be chosen to code the number of documents to discriminate (this will for example be the case for banknotes, when using the second sign for the mechanized discrimination of the face value of the ticket analyzed), the number bands remaining otherwise limited by the technological possibilities of analytical means working on very thin bands.

It will also be possible to print the graphics (on the front and / or overleaf) with other inks that do not react to excitement corresponding to coding in parallel bands (for example a infrared radiation).

This possibility can be used for banknotes, offset printing, and in particular intaglio printing, allowing easily a juxtaposition of colors, thanks to the cut rollers (there there are no "register" problems with colors, because we use the same printing plate).

Figure 3 makes it easier to distinguish the watermarked area corresponding to the first security sign 100, as it appears seen through transparency.

The watermarked network 100 is thus preferably periodic ( regular alternation of opaque and bright areas), and its period is noted P. In addition, as will be explained in detail below, this network watermarked has waves which are preferably (but not limitative) with sinusoidal surface mass profile.

Figure 3 also shows that the wave of the watermarked network 100 extends in a common DC direction which is essentially not perpendicular to the direction DD of the cutting strips of the second network 200.

In this case, the aforementioned directions DC and DD make between them a angle β which is here 45 °, which allows reading of ticket 1 in two perpendicular directions (parallel to the large edge, which is in general the case for processing machines, especially for banknotes bank, or parallel to the small edge).

As a variant, it is possible to choose other values for the angle β between the two directions above, but at the expense of the corresponding advantage. FIG. 15 illustrates a particular case where the directions DC and DD are essentially parallel, this case inducing a particular arrangement detection sensors, as will be described later with reference to this figure.

It should also be noted in FIG. 2 the presence of a particular phase shift for the waves of the first network 100 relative to the center of the square which is here at the intersection of the axes X'X and Y'Y of ticket 1.

The choice of such a phase shift, for example bringing as is the case here the edge of a strip at the center 0 of the square, will be a function of mode of analysis used and corresponding processing means.

We will see that this allows a sensor located at a distance any of the X'X or Y'Y axes to always receive the same signal (at π or 2 π near).

The arrangement illustrated in Figure 2 remains in any case the most interesting, because the arrangement of the two superimposed networks, namely the watermarked periodic network 100 and coded network 200 in parallel bands cutting the printed graphics, allows a reading of the ticket 1 globally indifferent (independent of the shaping, orientation and direction of document flow.

FIG. 4 illustrates the raised face of a matrix 110 allowing to stamp the form cloth during the production of the document, to obtain a watermarked periodic network similar to that of FIG. 2. This face in relief presents undulations, here sinusoidal, which propagate in a common direction DC inclined at 45 °.

The raised face of the matrix 110 thus presents a succession of hollow 111 and bumps 112 (better visible on the cross section of the FIG. 4), which make it possible to produce the alternately light zones 102 and opaque 101 for the watermarked network 100 of the document.

The associated section V of FIG. 5a, showing the variations of the areal mass in the watermarked area of the document (depending on the direction DC), is then in direct correspondence with the curve of the variations of relief of the matrix 110 illustrated in FIG. 5.

It is interesting to note in Figure 5a that the variations amplitude of the sine waves of the watermarked network are around the medium shot noted PM of the document (which allows independence of reading with regard to the shaping of the document).

Period P will preferably be chosen to be large compared to document dimensions, for example of the order of 10 mm for a banknote bank, so that the security sign 100 is as discreet as possible. he the same goes for the side of the square, which will be for example of the order of 60 mm.

The sections of Figures VI to IX associated with the figures allow by elsewhere to better distinguish the particular bevel from the edges 113 of the matrix 110. This beveling is in fact organized either downwards (edges chamfered 113 '), or upwards (chamfered edges 113 ") relative to in the mean plane of the raised face of the matrix 110.

This results in “bevelled” edges for the watermarked area, as can be seen from curves 6a to 9a giving the variations corresponding to the surface mass, on either side of the plane medium PM of the document.

We thus create a watermarked square with "lace" edges, which avoids sudden contrast transitions around the area watermarked, and further accentuates the discretion of the security sign.

Figure 12 illustrates (in transparency) the watermarked periodic network 100 obtained with a form cloth previously stamped with the matrix 110 above: note in particular the bevelled edges 103 of the square.

The opaque 101 and light 102 areas correspond to which has been previously described with reference to FIG. 3.

Figure 2 shows on a larger scale the area of ticket 1 where the two security signs 100 and 200 are superimposed.

The banded zones 101 and 102 of the watermarked periodic network 100, alternately opaque and clear, have the same width which is equal to the half-period P / 2 of the sine wave of said network.

The inclination of these bands 101 and 102 is identified by the angle β between the directions DC and DD (the angle β here is 45 °).

FIG. 13 also makes it possible to distinguish the parallel bands coded 201, 202 of the second security sign 200 corresponding to the cutting of the printed graphics.

The coded bands have the same width e which is determined, in most cases, according to the watermarked network, i.e. more precisely of the period P and the angle β.

FIG. 13 shows a right triangle ABC corresponding to a particularly advantageous arrangement for reading the document, a triangle whose hypotenuse AB corresponds to the width e of each of the bands 201 or 202, and one side of which corresponds to the half-period P / 2: so we have the relation e = P 2sinβ

In the particular case illustrated here, we have β = 45 °, therefore e = P 2 which corresponds for example to a strip width of 10 mm (with six strips), for a period of 14.14 mm.

However, the above relationship can only be used within certain limits, that is, as long as the angle β is greater than a reference angle β _o corresponding to a bandwidth e _o reaching half the width ( 1) of the document: this borderline case would indeed correspond to the presence of two bands, symmetrical with respect to the axis X'X.

For example, with a banknote whose width would be of the order of 80 mm, there will be a reference angle β _o of the order of 10 °.

When the angle β becomes less than this reference angle β _o , the width e of the strips 201, 202 for cutting the printed graphics is essentially chosen according to the coding sought.

The particular case of a zero angle is illustrated in Figure 15: the bands 101, 102 of the first network 100 are then orthogonal to the bands 201, 202 of the second network 200, and we can then choose a width e advantageously equal to the half-period P / 2 (the representation would then correspond to a perfect grid of the square in six bands orthogonal).

In practice, we will first choose the number of bands of cutting according to the number of documents to be coded and techniques of manufacture making it possible to produce these coded tapes, and also symmetry constraints.

This choice will also be guided by the precision of the reading used for document analysis. We will then determine the possible angles β, it being understood that an angle of 45 ° offers the maximum advantages, as explained above.

The document thus comprising two superimposed security signs 100, 200 of the aforementioned type is very interesting insofar as the superposition of these two signs has the effect of affecting the reading individual of said signs.

We thus manage to considerably increase the efficiency authentication.

When Note 1 is a banknote, the first sign of security 100 and the second security sign 200 are used for authentication of the ticket, and the second security sign 200 also serves to discriminate the face value of said ticket.

This will emerge more clearly from the variant of the analysis method and of the associated device, which will now be described with reference to Figures 14 to 17.

Figure 14 illustrates the area of ticket 1 where the two signs of safety 100 and 200 are superimposed (as for figure 12), with in plus a reading strip 301 equipped with detection means.

The detection means are here in the form of sensors 300, with at least one sensor per coded band 201 or 202 of the second network 200 (here one per band).

These resources are organized in a general direction D which is perpendicular to the direction DD which is that of the scrolling of the document in the reading machine (the direction DD is also that of the tapes coded 201, 202), and with a prohibition d equal to the width e of said coded bands 201 or 202.

It is specified that by “sensor” is meant a sensor intended for collect the response of the coded tape to elimination by radiation elementary with wavelengths λi. And in the context of the invention, this sensor can be the same to collect elementary responses from the coded band with different elementary radiations of length wave λ1, λ2 ... λn. In the remainder of this description, the term "Sensor" is thus to be understood broadly as a sensor capable of processing the responses of the coded tape to the different elementary radiation.

It is also advantageous for the detection means 300 to be located on the median axis (a) of the associated bands 201 or 202 of the second network 200: this avoids any risk of alteration of the analysis in the event of offset of the document with respect to the sensors of the reading module (it there would be a loss of signal by increased noise).

It can be a single reading strip, whose sensors include transmitting and receiving means, and under which the document to analyze.

It may alternatively be two superimposed reading bars, one of which includes transmitter means and the other of which receivers, and between which the document to be analyzed scrolls. Figure 14 then schematically shows either this single bar, or one of the two superimposed bars (the other being below it).

Figure 14 also shows that when a sensor 300 associated with a coded strip 201 or 202 reads a minimum of mass surface (sensor in the center of an inclined strip 102, on the axis of said strip), the sensor 300 associated with the symmetrical strip 201 or 202 (strip conjugate) reads a maximum basis weight (sensor in the center of a inclined strip 101, on the axis of said strip): this results from the fact that the arrangement of the watermarked sine wave profile network is such that there is phase opposition of the waves on either side of the X'X axis of the document, at the same distance from said axis.

More generally, there is at all times an interrelation between the response of a 201 or 202 coded tape and the response of the coded tape symmetrical (conjugate strip), when the document scrolls under the bar reading 301.

• on dispose des moyens de détection 300 à raison d'au moins un par bande 201, 202 du second réseau 200, ces moyens étant organisés selon une direction générale D perpendiculaire à la direction de défilement DD, avec une interdistance d'égale à la largeur e des bandes parallèles 201, 202 dudit second réseau ;
• on vérifie le codage du second réseau 200 en additionnant la réponse de chaque bande codée 0 ou 1 et de sa symétrique qui lui est conjuguée, afin d'éliminer l'influence du premier réseau 100, et en comparant les résultats obtenus aux valeurs théoriques de codage ;
• on analyse le premier réseau 100 par soustraction des réponses de chaque bande exempte de codage codée 0 et de sa symétrique.

So, in this particular variant:

• there are detection means 300 at the rate of at least one per band 201, 202 of the second network 200, these means being organized in a general direction D perpendicular to the direction of travel DD, with a prohibition equal to the width e parallel bands 201, 202 of said second network;
• the coding of the second network 200 is verified by adding the response of each coded band 0 or 1 and of its symmetric which is conjugate to it, in order to eliminate the influence of the first network 100, and by comparing the results obtained with the theoretical values of coding;
• the first network 100 is analyzed by subtracting the responses from each band free from coded coding 0 and from its symmetrical.

According to this vairante, by adding the response of each band coded and that of its conjugate band, we manage to both eliminate the signal from the first watermarked network, and the coding response is improved bands, for example the response to elementary radiation from wavelength λi: preferably, decoding by synchronous integration for each pair of coded bands (one pair being constituted by a coded band and its symmetrical or conjugate), then a mutual comparison of the results obtained with the theoretical values of coding.

And as we said, the description of this principle of recognition of the response of the two safety signs 100 and 200 to radiation from given infrared wavelength λi is actually implemented in the invention at several different wavelengths, which allow discriminate with certainty the watermarks of the first security sign 100.

By subtracting the responses of the couples of bands free of coding (coded 0), in particular the radiation absorption levels elementary, we can analyze the first watermarked network all the more easily that the signal-to-noise ratio of this network is significantly improved (there is indeed a signal whose amplitude is double thanks to phase opposition of the watermarked network between the coded bands conjugates of the same channel).

In the case of FIG. 15 for which the directions DC and DD are substantially parallel (the two superimposed networks then forming a grid of the watermarked area), it is necessary to modify the bar of reading 301.

Instead of a single row of sensors 300 arranged perpendicular to the direction of travel DD, the reading strip 301 then comprises two parallel rows of sensors 300 ′, 300 ", arranged perpendicular to the direction of travel DD, with one row per half strip: these two rows of sensors (each comprising three sensors 300 'or 300 "here) are then offset between them by a predetermined distance d ₁ which is preferably substantially equal to the half wavelength P / 2 of the first network, so as to find the previous phase opposition between homologous sensors.

The 300 'or 300 "sensors in the same row are also located on the median axis (a) of the associated coded bands 201, 202 of the second network, and are equidistant from each other by a distance d substantially equal to the width e of said coded bands.

• on dispose des moyens de détection 300', 300" à raison d'au moins un par bande 201, 202 du second réseau 200, ces moyens étant organisés selon une direction générale D perpendiculaire à la direction de défilement DD et situés sur l'axe médian a des bandes associées 201, 202, avec, d'un côté dudit axe X'X du document 1 des premiers moyens de détection 300' alignés entre eux, et, de l'autre côté dudit axe X'X, des seconds moyens de détection 300" également alignés entre eux mais décalés des premiers moyens de détection 300' d'une distance d1 sensiblement égale à la demi-longueur d'onde P/2 du premier réseau 100;
• on vérifie le codage du second réseau 200 en additionnant la réponse de chaque bande codée 0 ou 1 et de sa symétrique qui lui est conjuguée, afin d'éliminer l'influence du premier réseau 100, et en comparant les résultats obtenus aux valeurs théoriques de codage ;
• on analyse le premier réseau 100 par soustraction des réponses de chaque bande exempte de codage codée 0 et de sa symétrique.

So, in this variant:

• there are detection means 300 ′, 300 "at the rate of at least one per band 201, 202 of the second network 200, these means being organized in a general direction D perpendicular to the direction of travel DD and located on the axis median has associated bands 201, 202, with, on one side of said axis X'X of document 1, first detection means 300 'aligned with each other, and, on the other side of said axis X'X, second means detection 300 "also aligned with one another but offset from the first detection means 300 'by a distance d1 substantially equal to the half-wavelength P / 2 of the first network 100;
• the coding of the second network 200 is verified by adding the response of each coded band 0 or 1 and of its symmetric which is conjugate to it, in order to eliminate the influence of the first network 100, and by comparing the results obtained with the theoretical values of coding;
• the first network 100 is analyzed by subtracting the responses from each band free from coded coding 0 and from its symmetrical.

So here again we find the same analysis process with addition of the responses of the conjugate coded bands, and subtraction of the absorption levels of the pairs of bands for the channel (s) not used for coding (coded bands 0).

Such an analysis process is therefore interesting, because it allows a double analysis of the two overlapping safety signs with a single sensor strip (we saw above that we designated by the term "Sensor" a set which in reality makes it possible to collect responses to at least two illuminations of different wavelengths), and this notwithstanding the fact that the superposition of these two signs has the effect to affect the individual reading of each of them.

This analysis process will be detailed below, with reference to the FIG. 17 which schematically illustrates a complete device for analyzing signals from the different sensors, on the one hand to check the coding of the second network and validating the document analyzed when the network read is compliant, and on the other hand to analyze the first network and validate the document analyzed when the network read is also compliant.

There are of course multiple ways of making the bar. reading, as will emerge from the variants described below under example.

Reading strip 301 can have openings substantially circular equidistant 302 associated with each sensor 300, as shown in Figure 14.

Alternatively, slots 303 may be provided (Figure 16a): each slot is then inclined so as to be substantially perpendicular to the direction of propagation of the wave of the first grating (each slot is thus inclined at the same angle β relative to the DD scrolling direction).

According to another variant, there are provided cruciform openings 304 (Figure 16b) whose two branches are respectively parallel and perpendicular to the direction of propagation of the wave of the first grating. This further increases the integration area for the first network and have a higher average value for the measured signal, because an integrated sampling process is used here.

According to yet another variant illustrated in FIGS. 16c and 16d at least one of the sensors is multiple (here the six sensors are multiple). In FIG. 16c, each multiple sensor 300 is constituted by two identical identical sensors 300 ₁ arranged on either side of the median axis (a) of each coded strip 201 or 202. The response of the sensor 300 is then the sum of the responses from the two sensors 300 ₁ .

It is specified that the two sensors 300 ₁ can also be different, for example each dedicated to a specific elementary radiation.

In this case, the response of the sensor 300 may correspond to the individual responses of each sensor 300 _1.

In FIG. 16d, each multiple sensor 300 is constituted by four sensors (identical or not) 300 ₂ arranged in a square, the square being centered on the median axis (a) of each coded strip 201 or 202, and the edges of the square being parallel and perpendicular to the direction of travel DD.

Here again, it is specified that each sensor 300 ₁ and 300 ₂ , the pair of which constitutes a multiple sensor 300 may in reality be itself an assembly of sensors each dedicated to collecting the response of the ticket at a respective wavelength.

It goes without saying that the variants of FIGS. 16a to 16d can be adapted to the case of the bar with two offset rows illustrated in the figure 15, then with two offset rows of inclined or cruciform slots, or two offset rows of multiple sensors.

Generally, the sensors 300 or 300 ', 300 "of the strip 301 will preferably be organized to present the same gain and the same original setting, so as to balance the different paths.

The single or multiple sensors may be photo-diodes, or photo-transistors, or photo-resistant cells, each of these sensors being preferably associated with optical filters to perfectly fit the desired wavelength.

We will now describe a complete signal analysis device from the different sensors of the reading bar, with reference to Figure 17.

Here again, this device is only described for signal analysis received in response to illumination by a single wavelength. And in the part of the invention, this device will be implemented in response to illumination by different wavelengths, corresponding to different elementary radiation of authentication radiation.

We find the reading bar 301, here with six sensors 300 for a document with six coded bands parallel to the direction of scrolling, including three sensors producing a respective signal denoted SA, SB, SC, and three other sensors producing a respective signal SA ', SB', SC 'corresponding to the conjugate coded bands.

The analysis device comprises means 400 for processing signals from sensors 300.

These processing means comprise two units, each of which is associated with a network 100 or 200 of the document.

The first unit allows the verification of the coding of the second network of the scrolling document at the level of the sensor strip, and the validation of the document analyzed when this network is compliant.

This first unit comprises first of all summing means 401 associated with each pair of coded bands. The signals obtained thus correspond to signals SA + SA ', SB + SB' and SC + SC '(these additions include each time the sum of a signal and this same signal phase shifted by π), preferably with prior amplification by means 413 interlayer amplifiers. These signals are sent to associated integrator means 402 allowing integration over the entire length of the document analyzed.

We thus obtain signals IA, IB, IC associated with each pair of coded tapes. These signals are sent to comparator means 403 to compare the results obtained with the theoretical coding values from the second network of the document to be analyzed.

Preferably, switching means 408, 409 are provided. upstream and downstream of the integrating means, these switching means (shown here by switches) being controlled respectively by passing the front edge and the rear edge of the document in front of a fixed component, such as a photo-diode (at least one of the sensors of the as a variant, the reading strip can itself perform a function additional detection of the passage of the ticket, which avoids having to provide a separate photo-diode): the control means 408, 409 is here shown schematically by a central control unit 415.

Thanks to this fixed detection device (integrated photo-diode or separate), we are then guaranteed to integrate across the entire length of the document. This is particularly interesting in the case of banknotes of the same width and different lengths.

The comparator means 403 first make it possible to verify that each value IA, IB, IC is well within a predetermined range of which the limits are defined according to the inks, the opacity of the paper, and other parameters relating to the document concerned.

The comparator means 403 are equipped with a contrast alarm 410 intervening when a difference between the results is outside a predetermined range. In this case, all the differences I _i -I _j are compared with the limits of the range, and the alarm 410 intervenes if there is no ink reacting to the known excitation (infrared radiation for example), or if the ink does not react properly to this excitation.

As a variant, the contrast alarm 410 intervenes when a report between results is outside a predetermined range. The comparator means 403 then comprise amplifiers logarithmic reports and a window comparator (positive or negative). In this case, all Log values (li / l) are compared to range limits. This variant is interesting both for the symmetry of the results if the answers are reversed, for the high sensitivity for a given scale in small differences in contrast, and for the fact that we have a maximum response for black and minimum for white.

Preferably, the first unit finally comprises decoding means 411 downstream of the comparator means 403, in order to identify the document, and in particular when the document is a banknote, in order to discriminate the face value of the note. These decoding means 411 have in memory the inequalities I _i <I _j for each document, which makes it possible to easily identify the analyzed document.

The second unit firstly comprises differentiating means 404 associated with each pair of coded bands. The signals obtained thus correspond to signals ISA-SA'I, ISB-SB'I and ISC-SC'I, with there more preferably a prior amplification by amplifiers 413 dividers. Each difference corresponds, due to the phase opposition for the watermarked network, twice the starting signal cleared of disturbances due to the dirtiness of the document and the look of the paper.

There are also provided selector means 405, downstream of each. differentiating means 404, to keep only the responses relating to codeless bands (coded 0). These means are shown here by switches controlled by the central unit 415, the switch associated with the bands SC and SC '(coded 0) being here closed.

It is interesting to send the signals obtained to means additional summers 412 (the signals being in phase, one obtains indeed n times the signal, with here n = 1, 2 or 3).

There are then filter means 406 allowing filtering. signals at the fundamental frequency of the first network, which allows to isolate the useful signal. This signal is finally sent to means 407 of recognition and validation, in order to analyze the first network of the document, and validate the document when the watermarked network is compliant, or failing to activate an associated alarm 414. These means 407 could include a window comparator on the amplitude and / or a threshold detection of harmonic distortion, or a detection of the number of periods.

It goes without saying that we can group in a functional unit unique the amplifier means 413, summers 401 and integrators 402 of the first unit, and the amplifier means 413 and differentiators 404 of the second unit.

The method and the device for analysis which have just been described in detail greatly increase authentication assistance.

If the document is falsified, this may result from a breach of the coding in parallel bands (second network), but then the circuit decoding will not validate the document and also reading the network watermarked on the channel in question will not be possible because of the ink sensitive to infrared. It can also result from a falsification of the network watermarked periodic (first network), but then, if the amplitude is too high, detection is easy; if the phase is not respected, the signal from the channel difference is then very attenuated, and if the profile is not sinusoidal, the measurement of the harmonic distortion allows detection.

The invention is not limited to the embodiments which come to be described, but on the contrary includes all the variants including, with equivalent means, the essential characteristics set out above, and in particular those using several lengths simultaneously λ1, λ2, ..., λn.

Claims (32)

Method for authenticating a security document comprising a watermarked security sign (100), the method comprising: exposure of the watermarked security sign to authentication radiation, collecting the response of the watermark security sign to said authentication radiation, and comparing said response with a reference response in order to authenticate the document, characterized in that said authentication radiation comprises at least two elementary radiations, the spectral characteristics of each elementary radiation being different, and the reference response takes into account an expected response of the document to at least one elementary radiation. Method according to claim 1, characterized in that the reference response corresponds to a predetermined relationship between the responses of the watermark security sign to each elementary radiation. Method according to the preceding claim, characterized in that the said predetermined relationship is a differential between the responses of the watermark security sign to two elementary radiations. Method according to one of the preceding claims, characterized in that when the security sign is exposed to authentication radiation, the security sign receives elementary radiation at the same time. Method according to one of the preceding claims, characterized in that each elementary radiation is centered around a different wavelength. Method according to the preceding claim, characterized in that said wavelengths are infrared wavelengths. Method according to the preceding claim, characterized in that said wavelengths respectively comprise a wavelength of the order of 880nm and of the order of 1500nm. A method according to claim 6, characterized in that said wavelengths respectively comprise a wavelength of the order of 880nm and of the order of 2µm. Method according to either of the preceding claims, characterized in that the authentication radiation is composed of a sequence of respective pulses of one of the elementary radiations. Method according to the preceding claim, characterized in that during each pulse only one elementary radiation is emitted. Method according to either of the preceding claims, characterized in that the responses of the watermark security sign are collected in transmission through the document. Method according to one of the preceding claims, characterized in that the method comprises collecting the response from different regions of the document which are printed by different respective security inks, in order to collect for each region a specific response to a light excitation according to each of the respective wavelengths used to illuminate the document by elementary radiation. Method according to one of the preceding claims, characterized in that : the document is scrolled in a determined direction (DD), by simultaneously reading two superimposed networks (100, 200), with a first network (100) which is watermarked periodically, and whose wave extends in one direction common (DC) essentially not perpendicular and not parallel to the direction of travel (DD), and with a second network (200) organized into bands (201, 202) according to a binary coding (0 or 1), said bands extending parallel to the direction of travel (DD), and being coded perpendicular to said direction of travel, symmetrically on either side of the axis (X'X) of the document (1) which is parallel to said direction of travel ( DD), and said bands having the same bandwidth (e) given by the formula e = P 2sinβ , where P is the wavelength of the first grating (100) and β the angle between said common direction (DC) and said direction of travel (DD), detection means (300) are available at the rate of at least one per band (201, 202) of the second network (200), these means being organized in a general direction (D) perpendicular to the direction of travel (DD) , with a prohibition (d) equal to the width (e) of the parallel strips (201, 202) of said second network, the coding of the second network (200) is checked by adding the response of each band (coded 0 or 1) and its symmetric which is conjugate to it, in order to eliminate the influence of the first network (100), and by comparing the results obtained at theoretical coding values, the first network (100) is analyzed by subtracting the responses from each codeless band (coded 0) and its symmetric, the detection means (300) are located on the median axis (a) of the associated bands (201, 202) of the second network (200). Method according to the preceding claim, characterized in that the document (1) scrolling in a determined direction (DD), two superimposed networks (100, 200) are read simultaneously, with a first network (100) which is watermarked periodically, and whose the wave extends in a common direction (DC) essentially parallel to the direction of travel (DD), and with a second network (200) which is organized in bands (201, 202) according to a binary coding (0 or 1 ), said bands extending parallel to the direction of travel (DD), and being coded perpendicular to said direction of travel, symmetrically on either side of the axis (X'X) of the document (1) which is parallel to said direction of travel (DD), and said bands having the same bandwidth (e) substantially equal to the half-wavelength (P / 2) of the first network (100), and the method comprises the steps following: detection means (300 ′, 300 ″) are available at the rate of at least one per band (201, 202) of the second network (200), these means being organized in a general direction (D) perpendicular to the direction of scrolling (DD) and located on the median axis (a) of the associated bands (201, 202), with, on one side of said axis (X'X) of the document (1) of the first detection means (300 ') aligned with each other, and, on the other side of said axis (X'X), second detection means (300 ") also aligned with each other but offset from the first detection means (300 ') by a distance (d 1 ) substantially equal to the half-wavelength (P / 2) of the first network (100), the coding of the second network (200) is checked by adding the response of each band (coded 0 or 1) and its symmetric which is conjugate to it, in order to eliminate the influence of the first network (100), and by comparing the results obtained at theoretical coding values, the first network (100) is analyzed by subtracting the responses from each codeless band (coded 0) and its symmetric. Device for implementing a method according to one of the preceding claims, characterized in that the device comprises means for emitting authentication radiation around at least two different wavelengths. Device according to the preceding claim, characterized in that said means comprise two light sources (E1, E2) which emit around different wavelengths (λ1, λ2). Device according to the preceding claim, characterized in that the sources are combined into a single source. Device according to one of the three preceding claims, characterized in that the device comprises a receiver (R) capable of collecting the responses of the document to the excitations around the respective elementary radiations, and means for comparing these responses with reference responses stored in the device. Device according to one of the four preceding claims, characterized in that the device comprises a first source capable of emitting around 880nm, and a second source capable of emitting around 1500nm or 2µm. Device according to one of the five preceding claims, characterized in that the reference response corresponds to a predetermined relationship between the responses of the watermark security sign to each elementary radiation. Device according to one of the six preceding claims, characterized in that amplifying means (413) are provided between the sensors (300; 300 ', 300 ") and the associated summing (401) or differentiating (404) means. Device according to one of the seven preceding claims, characterized in that the reading strip (301) has substantially circular equidistant openings (302) associated with each sensor (300; 300 ', 300 "). Device according to one of Claims 15 to 21, characterized in that the reading strip (301) has slots-shaped openings (303) associated with each sensor (300; 300 ', 300 "), each slot ( 303) being inclined so as to be substantially perpendicular to the direction of propagation of the wave of the first grating of the document. Device according to one of claims 15 to 21, characterized in that the reading strip (301) has cruciform openings (304) associated with each sensor (300; 300 ', 300 "), the two branches of each opening (304) being inclined so as to be substantially parallel and perpendicular to the direction of propagation of the wave of the first grating of the document. Device according to one of the ten preceding claims, characterized in that at least one of the sensors (300; 300 ', 300 ") is multiple. Device according to the preceding claim, characterized in that the multiple sensor is constituted by two adjacent sensors (300 ₁ ) arranged on either side of the median axis (a) of each strip of the second network of the document. Device according to Claim 23, characterized in that the multiple sensor consists of four sensors (300 ₂ ) arranged in a square, the edges of the square being parallel and perpendicular to the direction of travel (DD). Device according to one of claims 15 to 23, characterized in that the sensors are capable of collecting the response of the document to each elementary radiation. Device according to one of the fourteen preceding claims, characterized in that the single or multiple sensors (300; 300 ', 300 "; 300 ₁ , 300 ₂ ) are photo-diodes, or photo-transistors, or cells photoresist, each of said sensors being associated with optical filters to calibrate at the desired wavelength. Device according to one of the fifteen preceding claims, characterized in that the sensors (300; 300 ', 300 ") of the bar (301) are organized to present the same gain and the same original setting, so as to balance the different channels. Device according to one of the sixteen preceding claims, characterized in that the reading strip (301) comprises a row of sensors (300) arranged perpendicular to the direction of travel (DD), said sensors being equidistant from one another distance (d) substantially equal to the width of the parallel strips of the second network of the document to be analyzed. Device according to one of the seventeen preceding claims, characterized in that the reading strip (301) comprises two parallel rows of sensors (300 ', 300 ") arranged perpendicular to the direction of travel, said rows being offset between they of a predetermined distance (d 1) substantially equal to the half-wavelength of the first grating of the document to be analyzed, and the sensors (300 ′ or 300 ″) of the same row being equidistant from one another distance (d) substantially equal to the width of the parallel strips of the second network of said document.

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