WO2014184506A2

WO2014184506A2 - Device and method for authenticating content in a closed container

Info

Publication number: WO2014184506A2
Application number: PCT/FR2014/051157
Authority: WO
Inventors: Pierre Paul Jobert; Jean Pierre Massicot; Alain Foucou
Original assignee: Advanced Track & Trace
Priority date: 2013-05-17
Filing date: 2014-05-19
Publication date: 2014-11-20
Also published as: FR3005739A1; WO2014184506A3; FR3005739B1

Abstract

The invention relates to a device (20) for authenticating content in a closed container (240) that is at least partially transparent for a light having a wavelength of 350 nanometers to 1000 nanometers, comprising: a means (205) for storing the measurement of the fluorescence spectrum of the content; at least two light sources each configured for sequentially emitting light radiation; at least one means (220) for optically concentrating the radiation emitted by one of the light sources; at least one means (225, 226) for collecting the light emitted by the content; at least one means (230) for determining the fluorescence spectrum emitted by the content; and a means (235) for identifying the nature of the content, on basis of the comparison of the fluorescence spectrum to at least one spectrum stored by the storage means.

Description

DEVICE AND METHOD FOR AUTHENTICATING CONTENT IN A

CLOSED CONTAINER

TECHNICAL FIELD OF THE INVENTION

The present invention provides a device and a method for authenticating contents in a container. It applies in particular to the industry of the traceability of wines, spirits, oils and / or perfumes. STATE OF THE ART

In a wine production and marketing chain, for example, it is necessary to ensure that the finished product meets the expected quality requirements. The main difficulty in performing such a check is that the finished product, in the case of wine, is sealed in a bottle. We can not physically access the wine to analyze a sample.

In some systems, as described in Chinese Patent CN101256143, a method of identifying wines in a closed bottle constructed on the exploitation of Raman spectroscopy is detailed. It is recalled that "the Raman effect" is a physical effect according to which a medium can slightly alter the wavelength of a light signal passing through it. It is recognized that by studying the shift between the altered wavelength and the original wavelength, it is possible to establish some properties of the medium.

Chinese Patent CN101871891 adds to the above patent the use of a database of Raman spectroscopy results to quickly identify bottled wine. The limitation of these systems is that the Raman signal, by its nature, is extremely weak. For this reason, the exploitation of Raman spectrometry hardly gives satisfactory results at a lower cost. In addition, such a device is difficult to port, because the portability leads to limitations of the sensitivity and therefore the performance of the analysis performed by the device.

OBJECT OF THE INVENTION

The present invention aims to remedy all or part of these disadvantages. For this purpose, according to a first aspect, the present invention aims at a device for authenticating a content in a closed container at least partially transparent for a light whose wavelength is between 350 nanometers and 1000 nanometers, which comprises:

a means for storing the measurement of a fluorescence spectrum of the content when the content is exposed to at least one radiation having a wavelength of between 350 nanometers and 1000 nanometers,

a container support,

- At least two light sources configured to emit, each, successively, a light radiation whose wavelength is between 350 nanometers and 1000 nanometers towards the container; each of these light sources being oriented, with respect to the container support, at an angle of between 10 ° and 90 ° to the tangent of the container surface to which said light source is oriented,

at least one means for optically concentrating the radiation emitted by one of the light sources,

at least one means for collecting the light emitted by the content, each collection means being oriented, with respect to the support of the container, at an angle between 10 ° and 90 ° with the tangent of the surface of the container towards which said means collection is oriented,

at least one means for determining a fluorescence spectrum emitted by the content,

a means for compensating the absorption, by the container, of the light resulting from the fluorescence and

a means for identifying the nature of the content, as a function of the comparison of the fluorescence spectrum determined during the step of determination compensated for the absorption by the container, and of at least one spectrum memorized by the means memorisation.

Thanks to these provisions, the device that is the subject of the present invention makes it possible to compare the fluorescence of a content in a container as a function of a reference fluorescence of the content without a container and analyzed beforehand. This device has the advantage of ensuring that the content has the qualities expected by the content manufacturing process, for example. It is noted that the fluorescence, ie the light emission caused by the excitation of a molecule (generally the absorption of a photon) gives a signal more intense than the Raman effect.

In embodiments, the determining means is configured to detect a three-dimensional spectrum, one of the dimensions representing wavelengths transmitted, one of the dimensions representing wavelengths collected and the third of the dimensions representing an intensity.

These embodiments have the advantage of enabling authentication of a more precise content,

In embodiments, the device that is the subject of the present invention comprises at least three light sources and:

at least two light sources are configured to emit radiation of identical wavelength and

- At least two light sources whose radiation is of identical wavelength are configured to emit synchronously.

The advantage of these embodiments is that they make it possible to illuminate the contents in the container according to two different angles. These provisions also make it possible to obtain a more accurate and reliable fluorescence content.

In embodiments of the device that is the subject of the present invention: the container is a bottle and

at least two light sources are positioned under the bottom of the bottle and are oriented towards the bottle bottom of the container.

These embodiments allow easy positioning of the device in an assembly line and along the wine bottle distribution chain, for example. The positioning of the light sources under the bottom of the bottle makes it possible not to disturb the movement made by the bottles along the assembly line. In addition, stray lights are reduced in this configuration.

In embodiments, at least two light sources are oriented so that the radiation of each of said light sources is concentric, with a center point of concentricity located inside the bottle.

These embodiments make it possible to generate, at the concentricity center of the light sources, an excitation and therefore an optimal fluorescence. In embodiments of the device that is the subject of the present invention:

- the container is a bottle,

at least two light sources are oriented towards the neck of the bottle.

The advantage of these embodiments is that they make it possible, because of the smaller volume to pass through for light radiation at the neck, to facilitate the determination of a fluorescence spectrum by the device.

In embodiments, at least two light sources are oriented so that the radiation of each of said light sources is concentric, with a center of concentricity a point near the center of the neck of the bottle.

These embodiments make it possible to generate, at the concentricity center of the light sources, optimum excitation and fluorescence.

In embodiments of the device that is the subject of the present invention:

- the container is a bottle,

at least two light sources are oriented towards the barrel of the bottle.

These embodiments allow easy positioning of the device in an assembly line and along the wine bottle distribution chain, for example.

In embodiments, at least two light sources are oriented so that the radiation of each of said light sources is concentric, with a center of concentricity a point of the near the wall of the barrel of the bottle.

Thanks to these provisions, the emitted rays are less likely to be disturbed by the shape of the bottle, more regular at the level of the drum than the bottom or neck.

In embodiments, at least one collection means is oriented to target the concentricity center of the light sources.

These embodiments allow the determination means to optimally detect a fluorescence spectrum generated by the concentric light beams.

In embodiments, the device of the present invention comprises for each wavelength emitted by one or more light sources, a collection means. These embodiments make it possible to optimize the determination of a fluorescence spectrum.

According to a second aspect, the present invention aims at a method of authenticating a content in an at least partially transparent closed container for a light whose wavelength is between 350 nanometers and 1000 nanometers, and which comprises:

a step of storing the measurement of a fluorescence spectrum of the content when the content is exposed to at least one radiation having a wavelength of between 350 nanometers and 1000 nanometers,

- At least two emission steps by light sources configured to emit, each, successively, a light radiation whose wavelength is between 350 nanometers and 1000 nanometers in the direction of the container; each of these light sources being oriented, with respect to the support of the container, at an angle of between 10 ° and 90 ° with the tangent of the surface of the container towards which said light source is oriented,

at least one step of optical concentration of the radiation emitted by one of the light sources,

at least one step of collecting the light emitted by the content, each collection means being oriented, with respect to the support of the container, at an angle between 10 ° and 90 ° with the tangent of the surface of the container towards which said means collection is oriented,

at least one step of determining a fluorescence spectrum emitted by the content,

a step of compensating for the absorption, by the container, of the light resulting from the fluorescence and

a step of identifying the nature of the content, as a function of the comparison of the fluorescence spectrum determined during the determination step compensated for the absorption by the container, and of at least one spectrum memorized by the means memorisation.

Since the advantages, aims and particular characteristics of the method that are the subject of the present invention being similar to those of the device that is the subject of the present invention, they are not recalled here. In embodiments, the step of storing the measurement of a fluorescence spectrum of the content comprises a step of storage complementary to an absorption rate of each possible container of the content in question, for at least one length of time. characteristic wave of the fluorescence of the content.

In embodiments, the method that is the subject of the present invention comprises a step of determining the container.

In embodiments, the container determination step includes a step of relative movement of the container having the contents with respect to a collection means a step of detecting each of the walls of the container.

In embodiments, the container determining step includes a step of measuring the relative refractive index of the container.

In embodiments, the container determining step includes a step of measuring the absorption rate of the container, as a function of the reflection coefficients on the outer and inner walls of the container.

In embodiments, the method that is the subject of the present invention comprises, iteratively, steps of identification of the content, after compensation for the absorption by the container and the container, as a function of the refractive index of the content.

In embodiments, the content is authenticated only if the container and the content correspond to a pair of containers and content that are stored together in a database. BRIEF DESCRIPTION OF THE FIGURES

Other advantages, aims and particular characteristics of the invention will emerge from the following nonlimiting description of at least one particular embodiment of the device and the sound or light signal transmission method, with reference to the accompanying drawings, in which: which :

FIG. 1 represents, schematically, a first particular embodiment of the device that is the subject of the present invention,

FIG. 2 is a diagrammatic and sectional view from above of a second particular embodiment of the device which is the subject of the present invention, FIG. 3 represents a particular step logic diagram of the method that is the subject of the present invention, and

- Figure 4 shows, schematically, a third particular embodiment of the device object of the present invention.

DESCRIPTION OF EXAMPLES OF EMBODIMENT OF THE INVENTION

The present description is given in a non-limiting manner.

As of now, we note that the figures are not to scale.

In addition, in FIGS. 1 and 2, the container 140, 240 is closed and at least partially transparent for a light whose wavelength is between 350 nanometers and 1000 nanometers

FIG. 1 shows a first embodiment of the device 10 which is the subject of the present invention. This device 10 comprises:

a means 105 for storing the measurement of a fluorescence spectrum of the content and an absorption rate of a container 140 for characteristic wavelengths of the fluorescence spectrum,

a support 145 of the container 140,

- four light sources 1 10, 1 15,

a means 120 of optical concentration of the emitted radiations for each light source 1 10, 1 15,

a means 125 for collecting the light emitted by fluorescence by the content,

a means 130 for determining a fluorescence spectrum emitted by the content,

a means 132 for compensating for the absorption, by the container, of the light resulting from the fluorescence and

a means 135 for identifying the nature of the content.

The container 140 is, for example, a bottle of wine, spirits or perfume.

The means 105 for storing the measurement of a fluorescence spectrum of the content when the content is exposed to at least one radiation having a wavelength of between 350 nanometers and 1000 nanometers is, for example, a memory connected to a spectrometer. This spectrometer detects a fluorescence spectrum of the contents and the memory connected to the spectrometer stores this determined fluorescence spectrum. To obtain the spectrum of the content, the content is exposed to the radiation of at least one light source, for example during its flow. Alternatively, the content is placed in a container of very small thickness and totally transparent for at least one wavelength of the radiation emitted towards the content and at least one wavelength characteristic of the fluorescence of the content. Alternatively, the spectrum is measured in a similar container, even identical to the container 140.

The holder 145 of the container 140 is configured to position an outer surface of the container 140 at a predetermined position, regardless of the container 140.

The four light sources 1 10, 1 15 are configured to emit, each, successively, a light radiation whose wavelength is between 350 nanometers and 1000 nanometers in the direction of the container 140. Each of these light sources 1 10, 1 15 is oriented, relative to the support 145 of container 140, at an angle of between 10 ° and 90 ° with the tangent of the surface of the container 140 to which said source 1 10, 1 15 light is oriented. These light sources 1 10, 1 15 are, for example, monochromatic or pseudo-monochromatic light emitting diodes whose emission spectrum width at mid-height is of the order of 10 nanometers. These four light sources 1 10, 1 15 are configured to emit, in pairs, radiation of a single wavelength.

The two light sources 1 10 configured to emit radiation of a first wavelength emit synchronously. Similarly, the two light sources 1 15 configured to emit radiation of a second wavelength, different from the first wavelength, emit synchronously. Each light source 1 10, 1 15 is configured to transmit continuously or cyclically, in a duty cycle of a fifth, for example. In the case where the emission is cyclic, the duty cycle is imposed by a switch connected to the power supply. The higher the current in a light-emitting diode, for example, the lower the duty cycle, so as to maintain the average current at the nominal level. Each pair of light sources 1 10, 1 15 has successively a period of time to transmit, continuously or cyclically. The four light sources 1 10, 1 15 are oriented concentrically with a point of concentricity (or convergence of the transmission axes) a point inside the container 140. The support of the container is configured so that this point of concentricity is inside the container 140. For example, these four light sources 1 10, 1 15 are positioned under the bottle bottom of the bottle 140.

Each optical concentration means 120 is, for example, a converging lens converging the radiations of all the light sources 10, 1 15 into a point area of one millimeter in diameter.

The means 125 for collecting the light emitted by the content is oriented, relative to the support 145 of the container 140, at an angle between 10 ° and 90 ° with the tangent of the surface of the container 140 towards which the collection means 125 is oriented. This collection means 125 is, for example, an optical fiber. This collection means 125 is oriented towards the center of concentricity of the light sources 10, 1 15. Preferably, the support of the container is configured so that the light that is reflected on the outer wall of the container is not reflected towards the collection means 125.

In variants, this collection means 125 is a lens assembly. In other variations, this collection means 125 is a combination of an optical fiber and a lens assembly.

The means 130 for determining a fluorescence spectrum emitted by the content is, for example, a spectrometer. The determining means 130 is configured to detect a three-dimensional spectrum, one of the dimensions representing wavelengths transmitted, one of the dimensions representing wavelengths collected and the third of the dimensions representing an intensity.

The means 132 for compensating for the absorption, by the container, of the light resulting from the fluorescence implements the step 332 exposed with reference to FIG.

The means 135 for identifying the nature of the content, as a function of the comparison of the fluorescence spectrum determined by the means 130, compensated for the absorption by the container, and of at least one spectrum stored by the memory means 105 is, for example, an electronic circuit. When the determined spectrum corresponds to one of the spectra stored by means 105 of storage, the identification means 135 displays, for example, the name of the identified content according to a name of the content associated with the spectrum stored by the memory means 105.

It is noted here that the comparison is carried out in several steps, for example as explained below.

Signal analysis involves, for example, an algorithm built on a Gaussian sum decomposition whose normalized intensity is compared with a reference spectrum. Each of these Gaussians (there may be up to ten) corresponds to a particular physical phenomenon. The position, in wavelengths, of these Gaussians depends on the type of product analyzed: red wine, white wine, oil, whiskey, etc. To compare red wines, for example, all Gaussians are centered on the same lengths wave. The width of Gaussians depends on the optical configuration of the system (spectrum of the source plus resolution of the spectrophotometer). Preferably, only their relative intensity is discriminant. The discrimination is carried out according to the evolution of the intensities of these Gaussian as a function of the excitation wavelength.

In the case where a plurality of fluorescence spectra have been stored and it is desired to determine whether one of these spectra corresponds to the content, the spectra are normalized, for example so that the area below the spectrum (c ') that is, the integral of the function) is equal for the determined spectrum and for each of the stored spectra. Then, subtract the determined spectrum from each of the stored spectra. Then, we measure the area of this difference and we select the minimum area obtained with all the differences. If this minimum area is less than a predetermined limit value, it is considered that there is correspondence between the determined spectrum and the spectrum stored in the database that provided this minimum area difference. The identified content, in memory, with the stored spectrum is then displayed to the user. Otherwise, we consider that there is no match. And triggering information of the user, for example through an alarm signal.

It should be noted that the range of the measured spectrum is further defined by the programming of the spectrometer (the spectrum analysis instrument).

FIG. 2 shows a second particular embodiment of the device 20 of the present invention. This device 20 comprises: a means 205 for storing the measurement of at least one fluorescence spectrum of the content,

a support 245 of a container 240 of the contents,

four light sources 210, 215,

a means 220 for optically concentrating the radiation emitted for each light source 210, 215,

two means 225, 226 for collecting the light emitted by the content,

a means 230 for determining a fluorescence spectrum emitted by the content,

a means 232 for compensating the absorption, by the container, of the light resulting from the fluorescence and

a means 235 for identifying the nature of the content, as a function of the comparison of the fluorescence spectrum determined by the determination means 230 and at least one spectrum stored by the storage means 205.

Each of these means is similar to the corresponding lower reference means of 100, represented in FIG. Only the geometrical configuration of these different means differ in this embodiment.

The two means 225 and 226 for collecting the light emitted by the content make it possible to collect the fluorescent light on either side of the container 240 to provide two fluorescence spectra, which reduces the risk that an identification is disturbed by a defect in the container, for example a bubble or an inclusion.

FIG. 3 shows a particular embodiment of the method that is the subject of the present invention. This method 30 of authenticating a content in an at least partially transparent closed container for a light having a wavelength of between 350 nanometers and 1000 nanometers comprises a step 305 of storage including, iteratively, for each content which one wishes to memorize a spectrum of fluorescence:

two stages of emission by light sources,

a step of optical concentration of the radiation emitted by one of the light sources,

a step of collection of the light emitted by the content and

a step of determining a fluorescence spectrum emitted by the content. For each container whose contents are to be identified, without opening the container, the method comprises:

two steps 310 of emission by light sources,

a step 315 of optical concentration of the radiations emitted by the light sources into a point zone of the content,

a step 320 of collecting the light emitted by fluorescence by the content,

a step 325 for determining a fluorescence spectrum emitted by the content;

a step 330 of accumulation of the spectra determined for the different wavelengths and the different stages of light emission and

a step 335 for identifying the nature of the content, as a function of the comparison of the fluorescence spectrum determined during the determination step 325 and of at least one spectrum memorized by the storage means.

The step 305 of storing the measurement of a fluorescence spectrum of the content when the content is exposed to at least one radiation having a wavelength of between 350 nanometers and 1000 nanometers is achieved, for example, by the setting implementation of a memory connected to a spectrometer. This spectrometer detects a fluorescence spectrum of the content and the memory connected to the spectrometer stores this determined fluorescence spectrum.

Preferably, the storage step 305 also comprises a step 306 of complementary storage of the absorption rate of each possible container of the content considered, for at least one wavelength characteristic of the fluorescence of the content and, even more preferably, of the absorption spectrum of the container. This additional storage can be performed:

- from the knowledge of the material of the container and the thickness of the container considered,

by making a measurement on the container, with a transparency lighting emitting each of the characteristic wavelengths, or

correlatively to storing the fluorescence emission spectrum of the content. To implement this last case, a relative displacement of the container comprising the content with respect to the collection means and, possibly, with respect to the light sources is carried out.

During this movement, we identify each of the walls of the container because it forms a reflection on each of these walls. This gives the thickness of the container. In addition, the relative refractive index of the container with respect to the air and with respect to the contents is measured because this index influences the reflection coefficient on each of the walls of the container.

A container absorption rate for each wavelength emitted by a light source is correlatively measured. A step is thus taken to measure the rate of absorption of the container, as a function of the reflection coefficients on the outer and inner walls of the container. For example, the amount of light reflected on the inner wall of the container is divided by the amount of light that would be reflected on the inner wall of the container if no light absorption occurred in the container, estimated as a function of the index. of relative refraction of the container and the contents.

Note that the relative refractive index usually changes much more slowly in the visible or near-infrared spectrum than the absorption rate of a glass tinted in the mass.

From these measurements, made with each light source, the type of material of the container and its absorption rate for each wavelength characteristic of the fluorescence are determined by comparison with the contents of a database. content.

Indeed, the types of containers (if we take the wine for example) are particularly known, and therefore the measurement indicated above makes it possible to identify the type of container used. And therefore to refer to a database of container materials providing the absorption spectra.

The steps 310 of emission by light sources configured to emit, each, successively, a light radiation whose wavelength is made with light rays of wavelengths between 350 nanometers and 1000 nanometers, towards the container . Each of these light sources is oriented, with respect to the support of the container, at an angle of between 10 ° and 90 ° with the tangent of the surface of the container towards which said light source is oriented. The light sources are, by for example, monochromatic or pseudo-monochromatic light emitting diodes whose spectrum width at mid-height is of the order of 10 nanometers.

The optical concentration step 315 of the radiations emitted by one of the light sources is, for example, carried out by a lens configured to converge the radiations of all the light sources 1 10, 1 15 at a point of a light source. millimeter in diameter.

The step 320 of collecting the light emitted by the content is carried out, for example, by the implementation of an optical fiber oriented, with respect to the support of the container, at an angle between 10 ° and 90 ° with the tangent of the surface of the container to which the optical fiber is oriented. In variants, the step 320 of collection is performed by a lens assembly. In other variants, the collection step 320 is performed with a combination of an optical fiber and a lens assembly.

The step 325 for determining a fluorescence spectrum emitted by the content is carried out, for example, by a spectrometer.

The step 330 of accumulation of the spectra emitted by the content is carried out, for example, by adding values corresponding to the same wavelengths, in a memory. Each light source is, for example, one of the light sources as described in FIG.

The step 335 for identifying the nature of the content, as a function of the comparison of the fluorescence spectrum determined during the determination step 325 and of at least one spectrum stored during the storage step 305.

Preferably, before step 310, a step 308 is carried out for complementary identification of the material of the container, of its thickness with respect to the means of collection and the absorption spectrum of the container. This complementary identification is carried out with a relative displacement of the container comprising the content, with respect to the collection means and, possibly, with respect to the light sources.

During this movement, we identify each of the walls of the container because it forms a reflection on each of these walls. This gives the thickness of the container. In addition, the relative refractive index of the container with respect to air and in relation to the content, because this index influences the reflection coefficient on each of the walls of the container.

From these measurements, made with each light source, is determined, by comparison with the contents of a database, the type of material of the container and its absorption spectrum.

At the beginning of step 335, a step 332 is then performed to compensate for the absorption, by the container, of the light resulting from the fluorescence. For example, the fluorescence spectrum of the content, wavelength per wavelength, is divided by the product of the absorption spectrum of the container by the thickness of the container.

Step 335 thus makes an identification of the nature of the content, as a function of the comparison of the fluorescence spectrum determined during the determination step, compensated for the absorption by the container, and of at least one memorized spectrum. by the storage means.

Since the content is not yet identified at the beginning of step 335, its refractive index is still unknown. In variants, successive iterations are carried out to identify a content, obtain a refractive index of this content, stored in memory, and then identify the container, as a function of this index of refraction of the content. Once the container has been identified, the fluorescence spectrum is compensated according to the absorption of the container and a content is again identified. And so on until the container and content identifications are stabilized.

In variants, the content is authenticated only if the container and the content correspond to a pair of containers and content that are jointly stored in the database. Indeed, if the container has been replaced, considers that the content, even identified by its fluorescence spectrum, is not authenticated.

FIG. 4 shows a particular embodiment of the device 40 which is the subject of the present invention. This device 40 is similar to the device 10 shown in FIG. 1, the numerical references of the various elements being increased by 300. However, in this configuration, the concentricity point of the light sources 410, 415 and the collection means 425 is located near the barrel of the bottle. In addition, each light source 410, 415 and the collection means 425 are positioned towards the bottle drum and oriented, with respect to the container support, at an angle of between 10 ° and 90 ° with the tangent to the surface. of bottle at the level of the drum.

Claims

1. Device (10, 20, 40) for authenticating a content in an at least partially transparent closed container for a light having a wavelength between 350 nanometers and 1000 nanometers, characterized in that it comprises:

means (105, 205, 405) for storing the measurement of a fluorescence spectrum of the content when the content is exposed to at least one radiation having a wavelength of between 350 nanometers and 1000 nanometers,

a support (145, 245, 445) containing (140, 240, 440),

at least two light sources (1 10, 1 15, 210, 215, 410, 415) configured to emit, each, successively, a light radiation whose wavelength is between 350 nanometers and 1000 nanometers towards the container ; each of these light sources being oriented, with respect to the container support, at an angle of between 10 ° and 90 ° to the tangent of the container surface to which said light source is oriented,

at least one means (120, 220, 420) of optical concentration of the radiation emitted by one of the light sources,

at least one means (125, 225, 226, 425) for collecting the light emitted by the content, each collection means being oriented, relative to the support of the container, at an angle between 10 ° and 90 ° with the tangent of the surface of the container to which said collection means is oriented,

at least one means (130, 230, 430) for determining a fluorescence spectrum emitted by the content,

means (132, 232, 432) for compensating the absorption, by the container, of the light resulting from the fluorescence and

means (135, 235, 435) for identifying the nature of the content, as a function of the comparison of the fluorescence spectrum determined during the determination step compensated for the absorption by the container, and of less a spectrum stored by the storage means.

The device (10, 20, 40) according to claim 1, wherein the determining means is configured to detect a three-dimensional spectrum, one of the dimensions representing wavelengths emitted, one of the dimensions representing wavelengths collected and the third dimension representing an intensity.

3. Device (10, 20, 40) according to one of claims 1 or 2, which comprises at least three light sources and wherein:

4. Device (10) according to one of claims 1 to 3, wherein:

- the container is a bottle and

5. Device (10) according to claim 4, wherein at least two light sources are oriented so that the radiation of each of said light sources are concentric, with concentricity center a point located inside the bottle .

6. Device (20) according to one of claims 1 to 3, wherein:

- the container is a bottle,

at least two light sources are oriented towards the neck of the bottle.

7. Device (20) according to claim 6, wherein at least two light sources are oriented so that the radiation of each of said light sources are concentric, with concentricity center a point of the near the center of the neck of the bottle.

8. Device (40) according to one of claims 1 to 3, wherein:

- the container is a bottle,

at least two light sources are oriented towards the barrel of the bottle.

9. Device (40) according to claim 8, wherein at least two light sources are oriented so that the radiation of each of said light sources are concentric, with concentricity center a point of the near the wall of the barrel from the bottle.

10. Device (10, 20, 40) according to one of claims 5, 7 or 9, wherein at least one collection means is oriented to aim at the center of concentricity of the light sources.

1 1. Device (20) according to one of claims 1 to 10, which comprises a specific collection means, for each wavelength emitted by one or more light sources.

12. A method (30) for authenticating a content in an at least partially transparent closed container for a light having a wavelength between 350 nanometers and 1000 nanometers, characterized in that it comprises:

a step (305) for storing the measurement of a fluorescence spectrum of the content when the content is exposed to at least one radiation having a wavelength of between 350 nanometers and 1000 nanometers,

- At least two emission steps (310) by light sources configured to emit, each, successively, a light radiation whose wavelength is between 350 nanometers and 1000 nanometers towards the container; each of these light sources being oriented, with respect to the support of the container, at an angle of between 10 ° and 90 ° with the tangent of the supporting surface towards which said light source is oriented,

at least one step (315) of optical concentration of the radiation emitted by one of the light sources,

at least one step (320) of collection of the light emitted by the content, each collection means being oriented, with respect to the support of the container, at an angle between 10 ° and 90 ° with the latangent of the surface of the container to which said collection means is oriented,

at least one step (325) for determining a fluorescence spectrum emitted by the content, a step (332) of compensating for the absorption, by the container, of the light resulting from the fluorescence and

a step (335) for identifying the nature of the content, as a function of the comparison of the fluorescence spectrum determined during the step of determination compensated for the absorption by the container, and of at least one memorized spectrum by the storage means.

The method according to claim 12, wherein the step (305) of storing the measurement of a fluorescence spectrum of the content comprises a step (306) of complementary storage of an absorption rate of each possible container of the content considered, for at least one wavelength characteristic of the fluorescence of the content.

14. Method according to one of claims 12 to 14, which comprises a step (308) for determining the container.

15. The method of claim 14, wherein the step (308) for determining a container comprises a step of relative movement of the container comprising the content with respect to a collection means a step of detecting each of the walls of the container.

16. Method according to one of claims 14 or 15, wherein the step (308) for determining the container comprises a step of measuring the relative refractive index of the container.

17. Method according to one of claims 14 to 16, wherein the step (308) for determining the container comprises a step of measuring the absorption rate of the container, according to the reflection coefficients on the outer and inner walls. container.

18. Method according to one of claims 14 to 17, which comprises, iteratively, identification steps of the content, after compensation of the absorption by the container and the container, depending on the refractive index of the content.

19. The method as claimed in one of claims 14 to 18, in which the content is authenticated only if the container and the content correspond to a pair of containers and content jointly stored in a database.