WO2015052452A1 - Method and device for authenticating a product - Google Patents

Abstract

The invention relates to means for authentication and traceability for manufactured products. More particularly, it concerns combating the counterfeiting of manufactured goods. The method involves authenticating a product comprising a support irradiated with an ion beam, said support comprising, on one surface, traces corresponding the ion impact points, by: •obtaining an identifier unique to the product; • obtaining a first item of information relative to the traces present on the support; • comparing the first item of information with a reference item of information associated with the identifier; and generating an item of information indicating that the product is authentic, if the first item of information is substantially similar to the reference item of information.

Description

 Method and device for authenticating a product

Introduction

The present invention relates to authentication means for manufactured products, documents, works of art, etc. It relates more particularly to a physical medium, an infrastructure, and control means for verifying, with a high level of confidence, the origin or the authenticity of a product, in particular to fight against counterfeits or to enable the setting up traceability.

Prior art

Various means to authenticate a product, to prevent any illegal copy or ensure traceability, are now known.

The use of visible markers constitutes a first category. It is known, for example, to affix on a manufactured product, a label comprising a watermark, an inscription or a pattern printed using ink whose characteristics vary according to the lighting conditions, holograms, or a identification number, etc. Thus, the authenticity of the manufactured product on which the label is affixed is verified by ensuring that the label contains one of these elements. This verification can be done without a reading tool, visually. On the other hand, the level of protection offered by these solutions is very low, because the reproduction of these markers presents only few difficulties, or the simplicity of the control does not make it possible to distinguish between an original marker and a copy.

A second category includes invisible or coded markers. For example, it is possible to affix on a product a label comprising a barcode, a two-dimensional code, a bubble code, or a radio frequency RFID chip. It is also possible to introduce specific materials into the label holder, for example UV fibers, metal wires, magnetic particles, etc. Another possibility is to print on the label a pattern or code invisible to the naked eye, for example using a technique of micro or nano printing. These means, although more effective than those of the first category, can easily be decoded, to be reproduced. In addition, the use of RFID radio frequency chips is expensive, and therefore difficult to use on a large scale.

A third category of authentication and traceability means includes complex markers. By way of example, mention may be made of markers comprising DNA or nanoparticles, or markers having a specific and unique spectrum (infrared, gamma, etc.). To validate the authenticity of these markers, it is then essential to use control devices allowing an advanced physicochemical analysis. These means are usually only available in the laboratory. Verification is therefore expensive and difficult to implement, thus limiting its use to a wide range of manufactured products.

This is why there is a need for reliable authentication means, allowing easy verification of the authenticity of marked products, using devices easily accessible, simple to implement and inexpensive.

Summary of the invention

One of the objects of the invention is to provide authentication means for complex markers to be reproduced by an unauthorized third party. Another object of the invention is to provide a reliable authentication method, in particular based on the identification of characteristics of a marker generated randomly among a large number of possibilities. Another object of the invention is to provide an authentication infrastructure allowing the use of a simple device to implement, and inexpensive.

One or more of these objects are filled by the methods and devices of the independent claims. The dependent claims further provide solutions to these objects and / or other advantages.

More particularly, according to a first aspect, the invention relates to a method for authenticating a product comprising an irradiated support using an ion beam. The support has on a surface traces corresponding to the points of impact of the ions. The authentication method comprises the following steps: • obtaining a product-specific identifier;

Obtaining first information relating to the traces present on the support;

Comparing the first information with reference information associated with the identifier; and generating information indicating that the product is genuine, if the first information is substantially similar to the reference information.

By obtaining the identifier of the product, the method can compare the first piece of information relating to the traces with the previously recorded reference information, for example during a step of marking the product with the support. If the first information and the reference information do not match, then it is possible to identify that a change of the medium could have been achieved in this time interval or that the medium is not the one assembled during the step of marking the product: the product can not be authenticated anymore.

Typically, the support is attached to the product, so that the marker is inseparable from said product. The support may be included in a marker comprising a base and fixing means. The base can be used in particular as an assembly support on which the support is arranged. The base has, for example, a level of rigidity and / or elasticity sufficient to limit the mechanical deformations experienced by the support in the event of mechanical stresses exerted on the marker. The base also facilitates the assembly of the marker on a product. The base may be provided with a fixing means, for example a layer of adhesive substance covering a surface of the base. Thus the base can be easily attached to a surface of a product, a label of said product or a surface of a product housing. Alternatively, the base can be an integral part of a product element. The base may for example be formed by a surface of a package or a housing of the product, by a film and / or a sheet used by a product label to present information such as the name of the product, its characteristics. , its provenance, etc. Typically, the ion beam comprises ions whose energy is substantially between 5 MeV / u at 100 MeV / u. The ion beam is for example a beam of carbon ions 13 ( ¹³ C).

Advantageously, the density of the traces on the support is at least 5.10 traces per cm ² .

The support may be carried out in one or more of the following materials: polymer, for example cellulose acetate, polyethylene, polyethylene terephthalate, polycarbonate, polyimide, polypropylene, polyvinylidene fluoride, organic glasses (CR39, MR8, etc.), glass or crystal, for example quartz, garnet, etc. These materials are easily accessible, on an industrial scale, and generally inexpensive.

A protective layer may be disposed on the support. The protective layer is for example a polymer membrane, allowing an optical device to photograph the support. The protection of the support is thus improved, but the pattern constituted by the traces always recognizable.

For example, the support may have a thickness of 1.45 mm, be made of polycarbonate, and irradiated with a beam of carbon ions at a fluence of 1 ^e6 ions / cm ² . Once revealed, the traces on such a support have a mean diameter substantially equal to 2 μιτι.

Means of protection against an attempt to detach the support may be implemented so as to damage the support during such an attempt, and / or to allow the detection of such an attempt. In particular, the base and / or the support may be designed so as to decompose, tear, or become unreadable or incomplete, in case of an attempt to separate the product. The base and / or the support may for example comprise pre-cut marks delimiting a plurality of sub-sections, said marks being arranged so that the base and / or the support are cut out according to said subsections in the event of an attempt to dissociate . Support can also be attached to the base using a powerful fastening means, for example an adhesive substance with high fixing performance, making the separation of the support of the complex base without damaging the support.

Prior to the fixation step, an optional processing step for revealing the traces can be implemented. The revelation step allows for example to enlarge the diameter of the traces. The treatment may comprise a chemical bath step in a strong base or a strong acid, depending on the nature of the materials of the support, raised to a high temperature, typically between 70 and 80 ° C. The revelation time to which the support is subjected is directly related to the desired diameter of the pores corresponding to the traces of impacts.

The pattern formed by the traces is a unique stochastic figure. The ion beam behaves like an excellent random generator. Thus, for 50 traces, the probability of obtaining twice the same pattern is substantially equal to -> - Moreover, the traces obtained are invisible to the naked eye, and typically have a mean diameter of a few μιτι.

The product identifier can be obtained by reading a code printed on the product. For example, a code including the identifier can be printed on the product. The code can be printed on a marker on which the medium is also arranged. The code is for example a two-dimensional code ("QR code" in English) in which the product identifier is stored.

The first information can be obtained by acquiring an image of the traces; the reference information being a reference image of the previously recorded traces. The reference information is for example an image of the traces, made during the assembly of the support on the product, and stored in storage means. It is thus possible to compare the image of the traces taken by the authentication device with an image of the traces recorded during the installation of the support on the product. Alternatively, the first information can be obtained by acquiring an image of the traces, then calculating a signature from said trace image; the reference information being a previously recorded signature of the traces. In particular, the signature can be calculated according to the positions and the diameters of the traces. It is thus possible to compare the signature calculated by the authentication device with the recorded signature for example during the assembly of the support on the product.

According to a first variant, the acquisition of the trace image can be carried out with a simple and easily available optical device having a magnification factor typically between 10 and 1000 times. According to a second variant, the optical reading of the traces of the membrane is carried out by means of an optical reader by Fourier transform.

The first information is for example substantially similar to the reference information if a similarity rate between the first information and the reference information is greater than or equal to a confidence level.

According to a second aspect, the invention relates to an authentication device adapted to implement the method according to the first aspect.

According to a third aspect, the invention relates to a computer program comprising instructions for performing the steps of the method according to the first aspect, when said program is executed by a processor.

Each of these programs can use any programming language, and be in the form of source code, object code, or intermediate code between source code and object code, such as in a partially compiled form, or in any form what other form is desirable. In particular, it is possible to use scripting languages, such as in particular tel, javascript, python, perl that allow "on demand" code generation and do not require significant overhead for their generation or modification. According to a fourth aspect, the invention relates to a computer-readable recording medium on which is recorded a computer program comprising instructions for executing the steps of the method according to the first aspect.

The information carrier may be any entity or any device capable of storing the program. For example, the medium may comprise storage means, such as a ROM, for example a CD-ROM or a microelectronic circuit ROM, or a magnetic recording means, for example a diskette or a hard disk. On the other hand, the information medium may be a transmissible medium such as an electrical or optical signal, which may be conveyed by an electrical or optical cable, by radio or by other means. The program according to the invention can be downloaded in particular on an Internet or Intranet network. Alternatively, the information carrier may be an integrated circuit in which the program is incorporated, the circuit being adapted to execute or to be used in the execution of the method in question.

Brief description of the figures

Other features and advantages of the present invention will become apparent from the following description of embodiments with reference to the accompanying drawings, in which:

FIG. 1a is a diagram, with an overall plan, of a marker according to a first embodiment of the invention;

FIG. 1b is a diagram, with a sectional view, of a marker according to the first embodiment of the invention;

FIG. 2a is a diagram of a device for producing markers according to the invention;

FIG. 1b is a sequence diagram of a method of manufacturing markers according to the invention; FIG. 3 is a photograph, taken under the microscope, of a part of a support of a marker according to the invention, irradiated with a carbon ion beam 13;

FIG. 4a is a detail of an image of an irradiated support, on which three traces of impacts are visible;

FIG. 4b is a sequence diagram of a method according to the invention for calculating a signature for a marker;

FIG. 4c is a block diagram of a characterization device according to the invention;

FIG. 5a is a sequence diagram of a method according to the invention for marking a product;

FIG. 5b is a diagram, with an overall plan, of a marker according to the second embodiment of the invention;

FIG. 6 is a sequence diagram of a method for authenticating a product according to the invention;

FIG. 7 is a diagram of a control device according to the invention. detailed description

A marker 100 according to one embodiment of the invention is shown schematically in FIG. 1a in the overall plane, and in FIG. 1b in sectional view. The marker 100 is especially intended to allow the marking of a document, a work of art, a manufactured product, such as a bottle, a garment, an electronic equipment, a container, etc. The marker 100 is designed to be associated with an object such as a product. Typically, the marker 100 is attached to the object to be identified, so that the marker is inseparable from said object. The marker 100 is a means for enabling the authentication or identification of the object with which it is associated, in particular to fight against counterfeits, to control authenticity, or to allow traceability. The marker has a base, fastening means 112, a support 120, and optionally a protective layer 130.

The base 110 is used in particular as an assembly support on which the support 120 and the protective layer 130 are arranged. The base 110 generally has a level of rigidity and / or elasticity sufficient to limit the mechanical deformations experienced by the support 120 in the event of mechanical stresses exerted on the marker, in particular during transport, assembly operations and more generally during deformations of the surface of the product on which the marker is disposed. The base 110 also makes it easier to assemble the marker on a product. The base 110 may be provided with a fixing means 112, for example a layer of adhesive substance covering a surface of the base 110. Thus, the base may be easily fixed on a surface of a product, for example on a label of said product or on a surface of a product enclosure. Alternatively, the base 110 may be an integral part of a product element. The base 110 may be for example formed by a surface of a package or a product housing, by a film and / or a sheet used by a product label to present information such as the product name, its characteristics, provenance, etc. In the example of a bottle, the base 110 may be included in a section of the label stuck on the bottle. In the example of an electronic equipment, the base 110 may be a surface of a housing containing the electronic components.

The marker 100, in particular the base 110 and the support 120, is arranged so as to make any attempt to separate the product difficult without damaging the marker. For example, the base 110 and / or the support may be designed to decompose, tear, or become illegible or incomplete, in case of an attempt to separate the product marker. The base 110 may for example comprise pre-cut marks delimiting a plurality of subsections, said marks being arranged so that the base 110 is cut according to said subsections in case of an attempt to dissociate. The support can also be fixed to the base by means of a powerful fastening means, for example a substance adhesive with high fixing performance, making the separation of the support of the complex base without damaging the support.

Referring now to Figures 2a and 2b, respectively illustrating a device for producing markers 100 and a method of manufacturing markers 100. The support 120 of each marker 100 produced by implementing the manufacturing method comprises a stochastic pattern obtained by revealing latent traces created in the material of the support 120 by irradiation with a beam of heavy ions. This so-called "trace etching" technique is commercially available and used industrially. It makes it possible to obtain nanopores in the support 120. The technique of engraving traces is described in particular in the following documents:

• Nuclear tracks: A successful story of the 20th century, S.A.Durrani, Rad. Meas.

 34 (2001), 5-13;

• Nuclear tracks: Present and future perspectives, R. lie et al., Rad. Meas. 36 (2003) 83-88;

• Industrial applications of ion tracks technology, Hanot H., E. Ferain, NIM B 267 (2009) 1019-1022.

The marker generating device comprises a generator 200 for producing a beam 205 of high energy ions, typically from 5 MeV / u to 100 MeV / u, depending on the nature of the ion and the thickness and nature of the support. 120.

In a first step 310, a membrane to be irradiated 260 is disposed in an exposure device 230. The membrane to be irradiated 260 may be in the form of sheets or rolls. It is placed in a plane orthogonal to the axis of the beam 205. The membrane 260 is made of a material chosen so that the surface of the membrane has latent traces, after being irradiated by the beam 205. The latent traces are typically nanopores positioned at the points of impact of the ions of the beam 205. The membrane 260 may for example be made in one of the following materials: polymer, in particular cellulose acetate, polyethylene (PET), polyethylene terephthalate (PETP), polycarbonate (PC), polyimide (PI), polypropylene (PP), polyvinylidene fluoride (PVDF), organic glasses (CR39, MR8, ...), glass, crystal as quartz or garnet, etc. The thickness of the membrane is chosen according to the characteristics of the beam 205, in particular the energy level of the latter, and the desired penetration depth of the ions. For example, for a beam whose energy is substantially equal to 1 MeV per nucleon, the penetration depth in a polycarbonate membrane is substantially 10 μιτι. For a beam whose energy is substantially equal to 10 MeV per nucleon, the penetration depth in this same membrane is substantially 30 μιτι. For a beam whose energy is substantially equal to 100 MeV per nucleon, the penetration depth in the same membrane is a few mm.

During a second step 320, the membrane 260 is irradiated by the beam 205. The impact surface of the ions of the beam 205 on the membrane 260 substantially corresponds to a disk, the probability of impact being maximum in the center of said disk and substantially distributed according to a Gaussian law, the total area typically ranging from 1 mm ² to a few cm ² , depending on the characteristics of the beam. To cover the entire surface of the membrane 260, scanning devices 210, 220 are also used. For example, horizontal scanning magnets 210 may be employed to scan the beam 205 over time in a first plane, so as to move the ion impact disk on the membrane 260 in that first plane. Vertical scanning magnets 220 are used to scan the beam 205 over time along a second plane orthogonal to the foreground, so as to move the spot beam onto the membrane 260 in this second plane. By operating the vertical magnets 220 and horizontal 210 over time, it is then possible to scan the entire surface of the membrane 260, without moving the latter. Alternatively, the exposure device 230 may comprise means for driving the membrane, so as to move the membrane 260 relative to the beam impact disk: for example, rollers may drive the membrane 260 in translation in the second plan, only the horizontal magnets 210 then being used to move the impact disk in the foreground. In addition to the characteristics of the membrane, the energy of the beam, the scanning speed of the beam on the membrane and / or the irradiation time are chosen according to the desired latent density of traces. Since the flux of the beam 205 expresses in ions per unit area and per second, the choice of the irradiation duration is then a function of the desired fluence (ions per unit area) and therefore the desired impact density. The higher the latent trace density, the higher the complexity of the resulting pattern. Thus, if we assimilate 1 μιτι ² to a pixel and if we consider a matrix of 200x200 pixels, the probability of impact at a given point is de- - hence the following table:

The number of possibilities corresponds to the number of different patterns possible for a surface of 2oox2oopm. During a third step 330, the irradiated membrane is subjected to a treatment with a developer device 240 so as to reveal the traces of impact of the ions, in particular by enlarging the diameter of the impact traces. The developer device 240 is for example a chemical bath comprising a strong base or a strong acid, depending on the nature of the membrane materials, raised to an elevated temperature, typically between 70 and 80 ° C. The exposure time to which the membrane is subjected is directly related to the desired diameter of the pores corresponding to the traces of impacts.

During a fourth step 340, in an assembly device 340, the irradiated and revealed membrane is used to assemble markers 100. The membrane is thus cut so as to obtain a plurality of supports 120. Each support 120 is then arranged on a base 110. Optionally, a protective layer 130 is disposed on the support 110. The protective layer is for example a polymer membrane, allowing an optical device to photograph the support 120. For example, Figure 3 shows a photograph taken under a microscope, a field of 5.10 ^{"cm 2} of a support 120 having a thickness of 1.45 mm of polycarbonate, irradiated by the beam 205 carbon ions, at a fluence of 1 ^e6 ions / cm ^{2, the} impact traces 122 of the ions on the support have a mean diameter substantially equal to 2 μιτι.

FIG. 4b illustrates, using a sequence diagram, a method of calculating a signature for a marker according to the invention. During a first step 410, a two-dimensional image of the irradiated surface of the support 120 is obtained. Then, in a second step 420, the two-dimensional image of the irradiated surface is analyzed so as to identify the zones corresponding to one of the impact traces 122. An image segmentation method can be implemented to identify each zone in the zone. which a disc corresponding to one of the impacts could be spotted. In a third step 430, the topological properties of the impact traces detected during the second step 420 are determined. FIG. 4a shows a detail of the image of the support, on which three impact traces 122a, 122b, 122c are visible. Each of the traces can be characterized by the position of the center of the corresponding disc C _a , C _b , C _c , and its radius r _a , ¾ r _c . During a fourth step 440, a signature S is computed from the properties of the impact traces obtained during the third step 430. The signature S is for example a vector describing the topological properties of the impact traces 122 identifiable using the two-dimensional image of the irradiated surface. The resulting signature S is unique to each marker 100 because the position, shape, and size of each impact trace form a unique identifiable pattern. Since the impact traces have a substantially cylindrical shape, it is possible to consider each impact trace as a perfect cylindrical shape, having a position C _a , C _b , C _c of its center of gravity, a radius r _a , ¾ r _c of the front disc and a height H of the cylinder. The signature S relating to ntraces of impacts can therefore be described as follows:

S = {Ci, C ₂ ..., C withCi = (XY r H _t ) In the context of a system using a two-dimensional image, the height of the cylinder is equal to zero for the calculation of the signature S. Thus, the signature S can in this case be described as follows:

S = {C _1} C ₂ ..., C _n } withCi = (^, ^,)

The signature S forms a unique and stable intrinsic descriptor making it possible to authenticate each marker 100 in a unique manner. The stability of this signature S is guaranteed by the rigidity of the irradiated support 120 and / or the base 110. In addition, the size of the support can be limited to a few millimeters, so as to render its sensitivity to physical distortions negligible.

The method according to the invention for calculating a signature may in particular be implemented using a characterization device 460 such as that shown diagrammatically in FIG. 4c. The characterization device 460 comprises an image acquisition module 470, and a processing module 480. The image acquisition module 470 comprises, for example, a photosensitive sensor, an optical element and a diffuse illumination, so as to enable obtaining a two-dimensional image of the irradiated surface of the support 120, whose resolution is sufficient to identify and characterize the impact traces 122.

According to a first variant, the image acquisition module comprises a microscope typically having a lens capable of enlarging the image by a factor that can be between 40 and 100.

According to a second variant, the acquisition module comprises an optical reader by Fourier transform. According to this variant, the irradiated membrane is exposed to a coherent light source, for example a laser, which makes it possible to obtain a diffracted image generated by each hole of the irradiated membrane. The diffracted image corresponds to the Fourier transform of the opening function, that is to say the Fourier transform of the random patterns present on the illuminated part of the membrane. The diffracted image can be recovered by an optical sensor such as a charge transfer device frequently designated by the acronym "CCD" in English terminology for "Charge-Coupled Device", a device known to those skilled in the art. With this second variant, we recover an enlarged image of one or more areas of the irradiated membrane, while avoiding the need for a microscope. This inexpensive variant to implement, is particularly suitable for commercial and / or industrial exploitation.

The image acquisition module 470 can be used to implement the first step 410 of the S signature calculation method. The processing module 480 comprises calculation means as well as a software platform for calculating and comparing data. signatures.

Referring now to FIG. 5a, illustrating by a sequence diagram, a method of marking a product P. In a first step 510, a signature Sp of a marker M _{P is determined} . The marker M _P is obtained by implementing the method of manufacturing markers previously described and illustrated in Figure 2b. The signature Sp of the marker M _P is calculated by implementing the method for calculating a signature previously described and illustrated in FIG. 4 b. Then, during a second step 520, an identifier ID relating to the product P is obtained or calculated. The identifier ID is unique to the product P: it may be, for example, a serial number, d a unique number corresponding to the product P, a unique reference, or any other information enabling the product P to be identified. For example, in the example of marking a batch of 100 telephones, the identifier ID may be a number serial or an identification number, unique to each of the 100 phones. During a step 540, the identifier ID relative to the product P and the signature Sp are associated and stored in storage means, for example in a database, so that it is possible to obtain later the Sp signature from the knowledge of the identifier ID. During a step 530, the identifier ID is stored on the marker M _P , and the marker M _P is assembled on the product P. As illustrated in FIG. 5b, the identifier ID can be stored on the marker M _P by printing a code 140 on the base 110 of the marker M _P. The code 140 is for example a two-dimensional code ("QR code" in English) in which the identifier ID is stored. Referring now to Figure 6, illustrating by a sequence diagram, a method of authenticating a product Pi labeled by the marking method described above and illustrated in Figure 5 b. In a first step 610, an image of a marker M _Pa is acquired on a product Pi. Then, during a second step 620, a signature Sp ₂ of the marker M _Pa is determined from the image. . The signature Sp ₂ of the marker M _Pa is calculated by implementing the method for calculating a signature previously described and illustrated in FIG. 4 b. Then, during a third step 630, the product Pi is authenticated by verifying the validity of the signature Sp ₂ for the product Pi. For this, the identifier ID corresponding to the product Pi is determined, for example by reading the code 140. present on the marker Pi. It then retrieves the signature Sp stored in the storage means corresponding to the identifier ID. The coherence C between the signature Sp ₂ and the signature Sp is measured, for example by calculating a similarity ratio between the signature Sp ₂ and the signature Sp. If the coherence C is greater than or equal to a confidence threshold, the product is deemed authentic. Otherwise, the authentication of the Pi product fails.

The authentication method previously described may also be implemented at the end of the process of marking a product P, illustrated in FIG. 5b, to check the validity and quality of the marker P and to ensure that the signature and the stored identifier are consistent with the product marker.

The method according to the authentication invention previously described and illustrated in FIG. 6 can in particular be implemented using a control device 700 such as that shown diagrammatically in FIG. 7. The control device 700 is for example a mobile terminal. The control device 700 comprises an image acquisition module 710, a processing module 720, a communication interface 730 and a user interface 740. The control device 700 comprises, for example, a photosensitive sensor, an optical element and diffuse lighting, so as to obtain a two-dimensional image of the irradiated surface of the support 120, whose resolution is sufficient to identify and characterize the impact traces 122. The acquisition module of images 710 also allows the reading of the code 140 if it is present on the marker. The module 710 can be used to implement the first step 610 of the authentication method. The processing module 720 comprises calculation means as well as a software platform for calculating, manipulating and comparing signatures, configured in particular to enable the calculations required for steps 620 and 630 of the authentication method. The communication interface 730 comprises the means necessary to communicate with the storage means so as to obtain the signature corresponding to an identifier. The user interface 740 notably allows an operator to control the implementation of the authentication method, and in particular to consult the result of the authentication method.

Claims

A method for authenticating a product comprising a support (120) irradiated with an ion beam (205), said support having on a surface traces (122) corresponding to the points of impact of the ions, characterized in that it comprises the following steps:

Obtaining (610) an identifier specific to the product;

Obtaining (610, 620) first information relating to the traces present on the support;

Comparing (630) the first information with reference information associated with the identifier; and generating information indicating that the product is genuine, if the first information is substantially similar to the reference information.

2. The method of claim 1, wherein the product-specific identifier is obtained by reading a code printed on the product.

3. Method according to any one of the preceding claims, wherein the first information is obtained by performing the acquisition of an image of the traces; the reference information being a reference image of the previously recorded traces.

4. Method according to any one of claims 1 to 2, wherein the first information is obtained by performing the acquisition of an image of the traces, then calculating a signature from said trace image; the reference information being a previously recorded signature of the traces.

5. The method of claim 4, wherein the signature is calculated according to the positions and the diameters of the traces.

The method according to any one of the preceding claims, wherein the first information is declared substantially similar to the reference information if a similarity rate between the first information and the reference information is greater than or equal to a threshold of trust.

7. Device for authenticating a product comprising a support (120) irradiated with an ion beam (205), said support comprising on a surface traces (122) corresponding to the points of impact of the ions, characterized in that it comprises:

An acquisition module configured to obtain (710) an identifier specific to the product and a first information relating to the traces present on the support, said first information being obtained by acquiring an image of the traces;

A calculation module configured to compare (720, 730, 740) the first information with reference information associated with the identifier, the reference information being a previously recorded reference image of the traces; and to generate information indicating that the product is authentic, if the first information is substantially similar to the reference information.

8. Device according to claim 7, wherein the acquisition module is configured to obtain the product-specific identifier by reading a code printed on the product.

9. Device according to any one of claims 7 to 8, wherein the acquisition module is configured to acquire an image of the traces, the calculation module being configured to obtain the first information by calculating a signature from said image traces; the reference information being a previously recorded signature of the traces.

10. Device according to claim g, wherein the calculation module is configured to calculate the signature as a function of the positions and the diameters of the traces.

11. Device according to any one of claims 7 to 10, wherein the calculation module is configured to declare the first information substantially similar to the reference information if a similarity rate between the first information and the reference information. is greater than or equal to a confidence level.

Computer program comprising instructions for performing the steps of the method according to any one of claims 1 to 6, when said program is executed by a processor.

A computer-readable recording medium on which a computer program is recorded including instructions for executing the steps of the method according to any one of claims 1 to 6.