WO2002084608A2 - Method for identification or authentication - Google Patents

Abstract

The invention relates to a method for identification or authentication of a marked object, characterised in that the ferromagnetic resonance of at least one ferromagnetic resonance active marker substance is detected. The determination of the ferromagnetic resonance is achieved by measuring the relative permeability ωr depending on the magnetic field strength. The ferromagnetic resonance properties of the superparamagnetic marker substance is recorded in the form of a signature. The ferromagnetic resonance is continuously measured and evaluated, for example in the form of a correlation between the relative permeability, the magnetic flux density and the magnetic field strength.

Description

 Patent application

"Identification or authentication procedure"

The present invention relates to a method for identifying or authenticating products or objects and the use of a ferromagnetic-resonance-active substance in product protection.

The identification or authentication of objects is particularly important for valuable or security products, such as Banknotes, value documents, check forms, personal documents or credit and check cards, as well as with branded products play an increasingly important role. A known possibility is to mark the objects in question by complex methods. Microengraving using laser technology is an example. Alternatively, objects are marked with special colors, phosphorescent or fluorescent pigments or other specific substances. The objects are then identified or authenticated by detecting these security features.

A disadvantage of the known identification or authentication methods, however, is that they are either complex with regard to the manufacture or incorporation of the marking or with regard to the verification of the security features introduced. Furthermore, many identification or authentication methods are not generally applicable, but are limited to certain areas of application due to the technology on which they are based. Another problem is that most of the identification or authentication methods have been used for some time and are therefore known to counterfeiters. For this reason, for most known identification or authentication methods, techniques already exist which are used to simulate a correct result. For many known security features, more or less good counterfeits are known. For this reason, there is increased interest in the market for new identification or authentication methods and also for new security features.

The object of the present invention is therefore to develop a new method for Providing identification and / or authentication of products or objects, which is also easy to use and also enables reliable identification and / or authentication.

The invention relates to a method for identifying or authenticating a marked object or product, which is characterized in that the ferromagnetic resonance is detected or determined by at least one ferromagnetic-resonance-active marker substance.

The present invention furthermore relates to a security feature for marking an object which comprises a ferromagnetic-resonance-active substance.

Another object of the present invention is the use of a ferromagnetic-resonance-active substance as a marker substance for product protection, in particular for the identification or authentication of an object or product.

The method according to the invention for identifying or authenticating a marked object creates the possibility of reliably identifying or authenticating marked objects or products by measuring the ferromagnetic resonance. This provides good protection against counterfeiting. It is particularly advantageous that the marker substance can be concealed or attached to the object in a non-localizable manner or introduced into the object, so that the principle of the identification or authentication method according to the invention is initially not simple in the examination of marked objects and how to find out. Even if the ferromagnetic-resonance-active marker substances are perceived optically, their purpose cannot be inferred at first, which increases the security against forgery of the method according to the invention.

The method according to the invention is also very simple and uncomplicated to use. For example, the ferromagnetic resonance of the marked objects or of the ferromagnetic-resonance-active marker substances can be measured, for example, with a simply constructed and inexpensive scanner. With the help of such a scanner, which is also known as portable handheld device can be manufactured, the ferromagnetic resonance of the ferromagnetic-resonance-active marker substance can be detected quickly, reliably and regardless of location.

The method according to the invention for identifying or authenticating a marked object is used to check the origin of the object or the product.

Authentication is essentially understood to mean a yes / no decision between the original and the forgery, while identification, at least in the case of a positive result, means an exact assignment, for example, to a specific company, to a specific brand, to a specific place of origin or production, for a specific production line or batch or for a specific production day. The ferromagnetic resonance of the marked object or the ferromagnetic-resonance-active marker substance is determined. The ferromagnetic-resonance-active marker substance can, for example, be added to the product or be connected to the object by suitable methods. In the method according to the invention for identifying or authenticating an object, it is generally not necessary to examine the entire object, but rather only certain areas marked with the ferromagnetic-resonance-active marker substance. Since these areas are only known to the manufacturer, it is all the more difficult to find the marker substances and to understand the functional principle of the method according to the invention, which further increases the security against forgery. Furthermore, even if the functional principle is known, it is not possible in a simple manner to produce a counterfeit of the marked objects, since the marker substances can be attached or incorporated at any point in or on the object. However, it is equally possible to introduce the marker substances into the whole object in a statistical distribution. In order to enable a more precise identification or assignment, it is also possible to mark the object not only with one but with several ferromagnetic-resonance-active marker substances. When using different marker substances or when using different markings, for example on different, precisely defined areas of an object, an additional code can thus be defined, with the aid of which further information, for example about the place of origin, can be encrypted. The method according to the invention opens up completely new possibilities in the field of combating product piracy. In view of the fact that the damage caused by product piracy annually is estimated at around DM 500 billion worldwide, it is understandable that the possibility of reliably identifying or authenticating marked objects is of enormous importance.

The identification or authentication method according to the invention is also referred to as an anti-fake method.

According to a preferred embodiment of the method the determination of the ferromagnetic resonance by measuring the relative permeability μ _r as a function of magnetic field strength H _ge s _a mt-

The magnetic field strength H _geS at _t mainly consists of that required to determine the ferromagnetic resonance

DC magnetic field Hoc and the high-frequency magnetic field HHF together.

Regarding the details of the ferromagnetic resonance determination, LR. Walker in Journal of Applied Physics, (29) 3, 1958, pp. 318-323 and Y.L. Raikher and V.L. Stepanov in Physical Review B, (50) 9, 1994, pp. 6250-6259.

In the anti-fake method according to the invention, the ferromagnetic property can be established either by means of an external high-frequency magnetic field HHF acting on the ferromagnetic-resonance-active substance and an external non-static direct-current magnetic field Hoc acting on the ferromagnetic-resonance-active substance, or by means of an external one the non-static high-frequency magnetic field HHF acting on the ferromagnetic-resonance-active substance and an external one on which static force acts on the ferromagnetic-resonance-active substance

DC magnetic field Hoc.

A static high-frequency magnetic field HHF is understood to mean the magnetic field component of the alternating electromagnetic field generated by the HF oscillator with a frequency v _s and a constant amplitude A _s .

Due to the measuring method, both the DC magnetic field Hoc act and the high-frequency magnetic field H _H F not only on the ferromagnetic-resonance-active substance but also on the product or on the object. This does not affect the measurement result.

Since the determination with the aid of a non-static high-frequency magnetic field requires a higher level of metrological and apparatus expenditure, the measurement of the ferromagnetic resonance by means of a non-static direct-current magnetic field H _D c and a static high-frequency magnetic field HHF is particularly important with regard to location-independent, simple handling of the method according to the invention prefers.

For example, the measurement of the ferromagnetic resonance in the latter measurement method can be carried out using a scanner which has an HF oscillator for generating a static high-frequency magnetic field HHF penetrating a sample, an electromagnet for generating a direct current magnetic field Hoc acting on the sample, and a signal detector for determining the HF _{component of} the magnetic flux BHF and a detector for determining the magnetic field strength H _geS amt and in which the direct current magnetic field Hoc has a non-static profile, in particular a non-linear profile, based on the time profile of the measurement.

Such a non-static DC magnetic field is very easy to implement in terms of circuitry. All you need is a simple copper coil connected to a capacitor via a thyristor. The capacitor is charged via a current source. After the capacitor has been charged, the charging current is interrupted. The capacitor can then be discharged via the coil by ignition of the thyristor, which results in a DC magnetic field which does not drop linearly with respect to the time course of the capacitor discharge. With the help of such a scanner, identification or authentication of the ferromagnetic-resonance-active marker substance can be carried out within a comparatively short time (less than 50 ms).

Since the scanner described is based on a simple measuring principle, which can be implemented by means of an electronic circuit in a small space, the scanner can be manufactured as a mobile, ie portable, device which can therefore be used anywhere. This opens up completely new applications, for example in the field of product or brand protection or Safety technology.

According to a preferred embodiment of the anti-fake method according to the invention, the ferromagnetic-resonance-active substance is incorporated into the object in homogeneous or heterogeneous form.

In this way, virtually the entire product is labeled with the ferromagnetic-resonance-active marker substance, which is particularly advantageous in the case of products which can be easily repackaged, since the marker substance can practically not be separated from the marked object, or only with great effort.

The proportion of the ferromagnetic-resonance-active substance is less than 10% by weight, in particular less than 1% by weight, based on the entire product. It is particularly preferred if the proportion of the ferromagnetic-resonance-active marker substance, based on the entire product or the entire article, is less than 0.1% by weight.

The amount of the ferromagnetic-resonance-active marker substance used for marking the object is preferably less than 50 μg.

Even with such small proportions or amounts of ferromagnetic-resonance-active marker substance, the anti-fake method according to the invention still delivers reliable results. The method can thus be carried out inexpensively.

Furthermore, reducing the ferromagnetic-resonance-active substance in the product to almost the detection limit has the advantage that the substance cannot be separated and used for incorporation into counterfeit products or markings. In addition, the separation of the substance, which is only contained in small proportions, requires a considerable amount of equipment, which many counterfeiters cannot achieve.

According to a further particularly preferred embodiment of the method according to the invention for identifying or authenticating a marked object, the ferrogagnetic-resonance-active substance is essentially arranged on the surface of the object. In this way, the marker substance can easily be attached to the objects or products, without having to be incorporated into the objects themselves. Such surface finishing of the objects can take place during the manufacturing process or, for example, also after the production of the objects in a separate step. Suitable methods for connecting the marker substance to the object include, for example, printing a marker which contains the ferromagnetic-resonance-active substance.

According to a further preferred embodiment of the method according to the invention, the proportion of the ferromagnetic-resonance-active substance is less than 100 μg / cm ² , in particular less than 50 μg / cm ² , based on the surface of the object.

As already described, the advantage of a low concentration of ferromagnetic-resonance-active marker substance lies on the one hand in increasing the profitability of the method according to the invention and on the other hand in increasing the security against forgery of the method.

According to a particularly preferred embodiment of the anti-fake method according to the invention, the ferromagnetic-resonance-active substance is part of the packaging of the object or is applied to the packaging of the object or product.

In this way, subsequent labeling of objects or products is possible. Furthermore, objects can also be marked in which it is not desired to add the marker substances to the objects themselves and where it is not possible to apply the marker substances to the surface of the objects, such as e.g. for powders or liquids.

According to a further preferred embodiment of the method according to the invention, the ferromagnetic-resonance-active substance is part of a security feature that is incorporated into the object and / or is applied to the object and / or the packaging.

A security feature is understood to mean a marking that the ferromagnetic-resonance-active substance in a homogeneous or heterogeneous Contains distribution and which is connected to the object to be protected against counterfeiting in a suitable manner, for example by printing, gluing, weaving, coating or impregnation, or is incorporated therein in a homogeneous or heterogeneous distribution.

The use of such a security feature is advantageous since the products or objects can be manufactured separately from the security features and the security features can be used universally. Thus, no changes in existing production processes are necessary. Such security features can be used, for example, to label a company's goods, which were manufactured in different production facilities, with a uniform label, which enables the objects to be reliably identified or authenticated.

It is particularly preferred that the security feature is a label or an adhesive, an emulsion paint or a lacquer.

The use of a label as a security feature which contains the ferromagnetic-resonance-active marker substance is particularly advantageous, since in this way the measuring point for the measurement of the ferromagnetic resonance is clearly defined and defined.

A particularly simple application also enables the use of an adhesive which contains the ferromagnetic-resonance-active substance. Such an adhesive can e.g. be used when gluing packaging of the objects or when affixing a label or other identification to the objects or the packaging of the objects. In this case, too, it is not necessary to examine the entire object or the entire packaging, but it is sufficient to examine only one of the adhesive points.

The ferromagnetic-resonance-active marker substances used in the identification or authentication method according to the invention are substances which have a ferromagnetic resonance. These include in particular ferromagnetic, ferrimagnetic, antiferromagnetic, paramagnetic and superparamagnetic substances. Superparamagnetic substances are particularly suitable as marker substances. The marked Products or objects can be equipped with one or more marker substances.

A substance is "superparamagnetic" if the magnetization achieved after removal of an external magnetic field during the application of the external magnetic field completely or almost completely decreases and has a high saturation magnetization. This property depends on the crystallite size of the substances and disappears when a characteristic size is exceeded.

The effect is based on the alignment of magnetic dipoles of the superparamagnetic substances similar to dipoles of a paramagnet in an external magnetic field and leads to a macroscopic saturation magnetization, which is of the order of 10 ⁵ Am ^"1. The initial magnetic susceptibility χ lies between the range from 1 to 100. For comparison, paramagnets such as molecular oxygen, platinum or aluminum have a value of approximately χ = 10 ^"6 and ferromagnets such as iron, cobalt or nickel have a value of χ = 10 ⁶ . Superparamagnetic substances, like paramagnets, have no hysteresis in the magnetization curve, but have a significantly greater magnetic susceptibility.

With regard to a precise definition of the term "superparamagnetism", I.S. Jacobs, C.P. Bean, "Fine Particles, Thin Films and Exchange Anisotropy (Effects of Finite Dimension and interfaces on Basic Properties of Ferromagnets)", in "Magnetism", Vol. 3, pp. 271-350, Academic Press, New York 1963.

The superparamagnetic substance can in particular be selected from the group of ferrites and metallic nanoparticles as well as mixed oxides of the general formula MeFe ₂ O ₄ , where Me stands for a divalent metal from the group iron, nickel, cobalt, chromium, molybdenum and vanadium.

According to a particularly preferred embodiment of the identification or authentication method according to the invention, the superparamagnetic substance consists of a mixed oxide of the general formula Me'χMeι.χFe ₂ θ ₄ where both Me and Me 'are divalent metals. Me 'stands for a divalent metal, especially iron, nickel, cobalt, chromium, molybdenum, vanadium, zinc, barium, strontium and magnesium, a selection for Me has already been explained above. With the above Formula Me'χMeι.χFe ₂ O ₄ , the index x is a number between 0 and 0.5, particularly preferably between 0.1 and 0.3. Here, a formula Me "γMe'Fe _2- γO ₄ would also be conceivable, where Me" is any trivalent metal and Y is a number between 0 and 0.5, particularly preferably between 0.1 and 0.3.

The use of superparamagnetic marker substances is of particular advantage, since even with knowledge of the chemical composition and the production method on the one hand and the ferromagnetic resonance properties (FMR properties) of the reference substance on the other hand, it cannot be specifically synthesized. Although it is possible to produce a substance of the same chemical composition based on the knowledge described above, the ferromagnetic resonance properties of the substance differ significantly from those of the reference substance.

The reason for this is that the method of manufacture of the ferromagnetic resonance-active substances has a considerable influence on their ferromagnetic resonance properties, which are already changed by slight deviations in the process parameters during manufacture or slight changes in the method of manufacture. The reason for this is that these properties are largely determined by physical properties, such as crystallite size, crystal structure, crystallinity,

Crystallite size distribution, particle size distribution, modification of the phase interface between crystals and matrix containing the particles can be determined.

These physical properties are in turn determined by production-specific parameters, such as, for example, temperature profile during the reaction, concentration gradient and stirring speed, profile of the pH value, ionic strength during production, changes in the concentration of the free emulsifier content over time. As a result of these parameters, which are difficult to set, even with knowledge of the method of production, a substance with the same ferromagnetic resonance properties is not always obtained. These FMR properties are often batch-specific. A non-reproducible FMR property is thus obtained, which is particularly advantageous for increasing the security against forgery of the identification or authentication method according to the invention. In this way it is possible, in the case of particularly valuable objects, such as art objects, for a specific identification or authentication of a Product or object. This opens up completely new possibilities in the fight against product piracy, since the use of superparamagnetic substances as marker substances in the identification or authentication method according to the invention means that the marker substances can practically not be reproduced even if they know their chemical composition, their physical properties and their method of manufacture.

According to a particularly preferred embodiment of the identification or authentication method according to the invention, the ferromagnetic resonance of the marker substance is determined and checked for identity with the ferromagnetic resonance of a superparamagnetic reference substance.

The term "identity" here means the positive result of a comparison of two substances whose ferromagnetic resonances differ only in the context of the measurement inaccuracy of the measurement method used.

The ferromagnetic resonance property of the superparamagenetic marker substance is preferably recorded in the form of a signature.

The term "signature" is understood to mean the course of a correlation of two measured values which are available in digital, ie electronically evaluable, form. In relation to the present case, this means that the ferromagnetic resonance is continuously measured and evaluated successively for a certain time range, for example in the form of a correlation between the relative permeability μ _r or the magnetic flux density B _D c and the magnetic field strength H _ge s _a mt-

The evaluation is carried out by suitable mathematical methods known to the person skilled in the art, for example by curve analysis or by simple evaluation of maxima and minima.

The following signature 1 shows a measurement of APG 933 from Ferrofluidics (1:10 diluted in PE).

According to a particularly preferred embodiment, the measured Signature compared with a previously measured signature of the reference connection for identity.

This enables a simple assignment (identification) of the measured marker substance to signatures determined beforehand on the basis of reference measurements.

By comparing the measured signature with a previously measured signature, the security against forgery of the identification or authentication method can be further increased. Due to the special properties of superparamagnetic substances, a marker substance (or the spectrum it measures) can be assigned to a specific spectrum that was previously measured using reference measurements. In this way it is possible, in the case of particularly valuable items, such as Art objects, to carry out a specific identification or authentication of a product or object. As already described, an exact reproduction of the shape of a signature is not possible even if the chemical composition of the superparamagnetic substance and the method of manufacture of this substance are known, since even the smallest deviations in the process parameters during manufacture or slight changes in the manner of manufacture result in significant changes in the signature cause.

Since predictions about the shape of a signature are only possible to a very limited extent even if the fundamentals of the security features are known, a high level of security against forgery is ensured here, with a simple measuring principle and simple handling of the method.

According to a further preferred embodiment of the method according to the invention for identifying or authenticating a marked object, the product or the object is a branded product, an object of art or a product of value or security. A branded product can in particular be a textile, cosmetic or pharmaceutical product, such as a medicament, in particular in the form of a tablet or capsule, or a detergent or cleaning agent, for example in solid, powdered or liquid form. A value or security product can in particular be a bank note, a bank product, a value stamp, a value document, a check form, a personal document, a credit or credit card or a Be a product safety product.

However, the object can also be a packaging or a label of a product, in particular a branded product, in whole or in part.

The ferromagnetic-resonance-active substance can either be incorporated into the object, the packaging or the label or can be applied to the product, the packaging or the label, in particular in the form of a label print, a coating or an adhesive bond.

Claims

claims:

1. A method for identifying or authenticating a marked object, characterized in that the ferromagnetic resonance is detected by at least one ferromagnetic-resonance-active marker substance.

2. The method according to claim 1, characterized in that the ferromagnetic resonance is determined by measuring the relative permeability μ _r as a function of the magnetic field strength H _geSa mt.

3. The method according to claim 2, characterized in that the ferromagnetic resonance is determined by means of an external static high-frequency magnetic field HHF acting on the substance and an external non-static direct-current magnetic field Hoc acting on the substance.

4. The method according to claim 2, characterized in that the ferromagnetic resonance is determined by means of an external, non-static high-frequency magnetic field HHF acting on the substance and an external static DC magnetic field HDC acting on the substance.

5. The method according to any one of the preceding claims, characterized in that the ferromagnetic-resonance-active substance is incorporated into the object in homogeneous or heterogeneous form.

6. The method according to any one of the preceding claims, characterized in that the proportion of the ferromagnetic-resonance-active substance - based on the entire product - is less than 10 wt .-%, in particular less than 1 wt .-%.

7. The method according to claim 6, characterized in that the proportion of the ferromagnetic resonance-active substance - based on the entire product - is less than 0.1 wt .-%.

8. The method according to any one of the preceding claims, characterized in that the amount of the ferromagnetic-resonance-active substance used to mark the object is less than 50 μg.

9. The method according to any one of the preceding claims, characterized in that the ferromagnetic-resonant substance is arranged essentially on the surface of the object.

10. The method according to any one of the preceding claims, characterized in that the proportion of the ferromagnetic resonance-active substance - based on the surface of the object - is less than 100 μg / cm ² , in particular less than 50 μg / cm ² .

11. The method according to any one of the preceding claims, characterized in that the ferromagnetic-resonance-active substance is part of the packaging of the object or is applied to the packaging.

12. The method according to any one of the preceding claims, characterized in that the ferromagnetic-resonance-active substance is part of a security feature that is incorporated into the object and / or is applied to the object and / or the packaging.

13. The method according to claim 12, characterized in that the security feature is a label, an adhesive, an emulsion paint or a varnish.

14. The method according to any one of the preceding claims, characterized in that the ferromagnetic-resonance-active substance is a ferromagnetic, ferrimagnetic, antiferromagnetic, paramagnetic and / or superparamagnetic substance.

15. The method according to claim 14, characterized in that the ferromagnetic-resonance-active substance is a superparamagnetic substance.

16. The method according to claim 15, characterized in that the superparamagnetic substance is selected from the group of ferrites and metallic nanoparticles and mixed oxides of the general formula MeFe ₂ 0 ₄ , where Me for a divalent metal from the group Fe, Ni, Co, Cr , Mo and V stands.

17. The method according to claim 15, characterized in that the superparamagnetic substance is selected from mixed oxides of the general formula Me'χMeι_χFe ₂ O ₄ , where Me 'is a divalent metal, in particular Fe, Ni, Co, Cr, Mo, V, Zn, Ba, Sr, Mg and Me is a divalent metal from the group Fe, Ni, Co, Cr, Mo and V.

18. The method according to any one of claims 14 to 17, characterized in that the ferromagnetic resonance is determined and checked for identity with the ferromagnetic resonance of a reference substance.

19. The method according to any one of claims 14 to 18, characterized in that the ferromagnetic resonance is recorded in the form of a signature.

20. The method according to claim 18 or 19, characterized in that the measured signature is compared with a previously recorded signature of a reference connection for identity.

21. The method according to any one of the preceding claims, characterized in that the object is a branded product, in particular a textile, cosmetic or pharmaceutical product, an art object or a valuable or security product, in particular a banknote, a bank product, a stamp, a document of value Check form, a personal document, a credit or check card, or a product security product.

22. The method according to any one of the preceding claims, characterized in that the object is a packaging or a label of a product, in particular a branded product, in whole or in part.

23. Security feature for marking an object comprising a ferromagnetic-resonance-active substance.

24. Use of a ferromagnetic-resonance-active substance as a marker substance for product protection.

25. Use according to claim 24 for the identification or authentication of an object.

26. Use according to claim 24 or 25, characterized in that an object or the packaging of an object is equipped with the ferromagnetic-resonance-active substance.