EP1839277A1 - Method for checking the authenticity of goods - Google Patents

Abstract

The invention relates to a method for checking the authenticity of goods, comprising marking and identifying the goods. According to the inventive method, (i) a mark is applied to the surface of an article in the form of a pattern with a pattern function M(x, y) in a marking step, said mark creating a local modification of the physically measurable properties of the surface of the article in the area of the mark which cannot be perceived by the eye; (ii) the transmission, reflection, or scattering of analytical radiation by the surface of the article is detected in accordance with the location coordinates (x, y) and the wavelength ? of the analytical radiation, a response function A(x, y, ?) that reflects the intensity of the transmitted, reflected, or scattered analytical radiation is determined in accordance with the local coordinates (x, y) and the wavelength ?, and the correlation of the response function A(x, y, ?) with the previously known pattern function M(x, y) is determined by means of a correlation analysis in an identification step, the mark being detected using the correlation.

Description

Method for checking the authenticity of goods

description

The invention relates to a method for checking the authenticity of goods

Trademark piracy is the illegal use of signs, names, logos (trademarks) and trade names used by brand manufacturers to label their products in the marketplace. Product piracy is the prohibited copying and duplication of goods for which the legitimate manufacturers have patent rights, design rights or copyrights. The brand and product pirate inherits the technical knowledge that a company has acquired through years of hard work and enormous financial resources in order to use it for its products. He uses the awareness of a brand that a brand manufacturer has acquired because of its quality products in order to deceive the consumer about the actual origin of the product and quality.

Product piracy has become a serious problem of the economy. The increasing importance of know-how in the information society, modern production techniques and the worldwide exchange of goods make it easy today to mimic profitable products almost identically and to channel them into lucrative domestic and foreign markets. Among others, the products of the chemical industry, the pharmaceutical industry, the cosmetics industry, the mineral oil industry, the vehicle construction and supply industry, the textile, shoe and clothing industry, the toy industry, the food industry, the electrical industry, digital media including software, film and Music as well as the products of banks and state.

Remedy can create so-called anti-counterfeiting technologies that allow authentication of goods. These must meet a range of requirements for anti-counterfeiting, durability, resilience, cost effectiveness, compatibility with distribution and consumer convenience.

Existing technologies for marking and authentication are, on the one hand, so-called "open technologies", ie technologies that work with visible marks for authenticity testing, and on the other hand "hidden technologies", ie those that work with invisible markings. Examples of open technologies B04 / 0145PC IB / XS / cd are the "Optical Variable Ink" (OVI), a printing ink that changes color depending on the angle of view, guilloche printing, intaglio printing, profile printing, holograms and watermarks.Examples of covert technologies are fluorescent colors that react to friction "Coin reactive ink", thermoactive colors, biologically, chemically or spectroscopically detectable elements, "taggants", microtext, raster text and digital watermarks, as well as machine-readable technologies such as chips that send data via radio waves and magnetic systems.

The object of the invention is to provide a method for checking the authenticity of goods. The object of the invention is in particular to provide such a method which is tamper-proof, durable, cost-effective and consumer-friendly.

The task is solved by a procedure for the authenticity check of goods comprehensively the marking and identification of the goods, with which one

(I) in a marking step on the surface of the product a mark in the form of a pattern with a pattern function M (x, y) applies, wherein by the

Marking a local change in the physically measurable properties of the

Surface of the product in the region of the marking is produced, and whereby this marking is imperceptible to the eye,

(ii) detects in an identification step the transmission, reflection or scattering of analysis radiation through the surface of the product as a function of the spatial coordinates (x, y) and the wavelength λ of the analysis radiation and thus determines a response function A (x, y, X) which the intensity of the transmitted, reflected or scattered analysis radiation as a function of the location coordinates (x, y) and the wavelength λ, and by correlation analysis the correlation of the response function A (x, y, λ) with the known pattern function M (x, y) determined, wherein the label is detectable by the correlation.

In a marking step (i), a marking in the form of a pattern is applied to the surface of the goods. The marking consists in a pattern-like change of the physically measurable surface properties of the goods, which is imperceptible to the naked eye. This can be done in the way that you have to exposing the marking surface of goods to any external action capable of altering their physically measurable properties, the external action following a pattern. The external influence is referred to below as environmental influence. External influences (environmental influences) include the action of light or, more generally, of radiation, of mechanical forces, of chemicals, of gases, of microorganisms, of radioactive radiation, of sound (for example ultrasound) or of heat onto the surface. The environmental influence can be exerted, for example, by irradiation or by applying chemicals to the goods surface, where by "chemicals" is meant all substances or substance mixtures which can react with the surface or with its ingredients.

Physically measurable in the sense of the present invention are the properties of the surface, if they can be detected via the interaction with an irradiation irradiated to the surface. Analysis radiation can be any radiation that interacts with the surface and can be transmitted, reflected or scattered by it. Examples are electromagnetic radiation, particle radiation (neutrons, radioactive alpha or beta radiation) or acoustic radiation (for example ultrasound).

It is essential that the environmental influence, which is suitable for changing the physically measurable properties of the surface, acts on the surface with a specific, known, location-dependent intensity distribution I (x, y). In other words, the effect of the environmental influence on the surface is not homogeneous but has an intensity pattern. This intensity pattern may be a simple geometric pattern, such as a striped pattern or a checkerboard pattern. The intensity pattern can also be completely irregular. For example, the intensity pattern may correspond to a trademark.

If the environmental influence acting on the surface is light with a specific wavelength or with a specific spectral distribution, the intensity must be equated with the radiation intensity, which is measured in W / cm ² . If the acting environmental influence is the effect of mechanical forces, which is caused, for example, by exposing a substrate surface to a sandblast, the intensity of this environmental influence can be equated with the number of sand particles striking the substrate surface per unit of time and area. If the environmental impact is the effect of chemicals or gases, the Inten It can be equated with the concentration of a specific substance at the site of the substrate surface.

The pattern is preferably produced by allowing the environmental influence to act on the surface by means of one or more masks which have a specific location-dependent transmission function T (x, y) (transmission pattern), and thus a location-dependent intensity distribution I (corresponding to the position-dependent transmission function). x, y) of the environmental influence, which generates the pattern as an image of the mask on the surface of the product. In this case, the pattern function M (x, y) underlying the pattern corresponds to the transmission function T (x, y) of the mask.

The transmission function T (x, y) describes the location-dependent permeability of the mask for the environmental influence. If the acting environmental influence is light, then the mask may for example consist of a substantially transparent to the light film containing a pattern printed, the printed areas for light of a certain wavelength or a specific wavelength range have a lower transmission or are substantially non-transparent , This film can be applied to the surface to produce the corresponding intensity pattern when irradiated on the surface. If the acting environmental influence is the mechanical effect on the surface caused by a sandblast, then the mask can be a template which has recesses through which the sandblast can act on the surface, but which otherwise covers the surface and before the action protected by the sandblast. If the environmental impact is the action of chemicals, gases or microorganisms, the mask may also be a template with recesses. In the case of chemicals or microorganisms, the formulations containing them may be streaked onto the template. The areas of the surface covered by the stencil are then protected from the action of the formulations while the surface in the recesses of the stencil comes into contact with the formulation.

But it is also possible to apply an intensity pattern without the use of a mask on the surface. Thus, when light is applied to a sample, the intensity distribution I (x, y) can be generated as a diffraction pattern on the surface. In a preferred embodiment of the method according to the invention, the marking is printed on the surface of the product by conventional printing methods such as high-pressure, intaglio, offset printing and ink-jet printing. This printing inks are used with minimal colorant content, which results in markings that are imperceptible to the eye. Preference is given to pigmented printing inks with high lightfastness. Suitable pigments are organic, for example, and inorganic pigments such as monoazo pigments, disazo pigments, anthanthrone pigments, anthraquinone nonpigmente, te anthrapyrimidine, quinacridone pigments, Chinophthalonpigmen-, dioxazine, flavanthrone, indanthrone, isoindoline, isoindolinone, isoviolanthrone, metal complex pigments, Perinonpig- elements, perylene pigments, phthalocyanine pigments, pyranthrone , Thioindigo pigments, triaryl carbonium pigments and inorganic white, black and colored pigments. It is also possible to use printing inks with soluble, lightfast dyes. Examples of these are soluble derivatives of phthalocyanine chromophore, preferably with metals such as copper, zinc or aluminum as the central atom.

In a further preferred embodiment of the method according to the invention, the label is generated photochemically. For this purpose, the surface is preferably irradiated with high-energy light, whereby photochemically induced local changes in the physically measurable properties in the surface. The irradiation is preferably carried out by a mask containing the pattern, that is by a mask having a transmission function corresponding to the pattern function.

In an identification step (ii), the transmission, reflection or scattering of analysis radiation through the surface of the product is detected as a function of the location coordinates (x, y) and optionally as a function of the wavelength λ of the analysis radiation.

The analysis radiation can have a discrete wavelength, for example the wavelength of the CO band at 5.8 μm (corresponding to 1720 cm ^-1 ) or else comprise a wavelength range, for example the entire visible spectral range from 400 to 800 nm. The transmission, reflection or scattering The analysis radiation through the surface is generally dependent on the wavelength of the analysis radiation, so that a response function A (x, y, λ) is obtained which determines the intensity of the transmitted, reflected or scattered analysis light as a function of the location coordinates (x, y, λ). y) and the wavelength λ. This response function can be used for discrete wavelengths λ or for one or more wavelength ranges Δλ (at For example, for the red, green and blue range of visible light).

The wavelength of the analysis radiation or its spectral composition depends on the type of marking. In general, it will be analytical light in the UV-VIS and / or NIR region of the spectrum. Thus, a marking with colorants will be analysis light in the UV-VIS range. If the marking consists of a pattern-shaped, light-induced aging of a plastic, which is reflected in the intensity of the CO band at 5.8 μm, the analysis radiation will comprise this wavelength.

In one embodiment of the method according to the invention, the reflection of the analysis light is determined by the surface. In this case, a telecentric measuring optics is preferably used. In a further embodiment of the method according to the invention, the scattering of the analysis light through the surface is detected. In this case, a confocal color measuring system is preferably used.

The reflection or scattering of the analysis radiation through the substrate surface as a function of the spatial coordinates (x, y) and the wavelength λ can also be detected with a color scanner or a digital camera.

The detection of radioactive or acoustic radiation (ultrasound) can take place with imaging methods known from medical diagnostics. Thermal infrared radiation can be detected with a thermal imaging camera.

From the detected intensity values, the response function A (x, y, λ) is generally determined using a digital image evaluation system.

An answer function is obtained, which reproduces the intensity of the transmitted, reflected or scattered analysis radiation as a function of the location coordinates (x, y) and optionally of the wavelength λ.

In a further step, the correlation of the response function A (x, y, λ) with the known pattern function M (x, y) is determined by correlation analysis, the marking being detectable by the correlation in such an authenticity check of the product. The correlation analysis is a known mathematical method for the recognition of characteristic patterns. Methods of correlation analysis have been extensively described in the literature. It is examined to what extent the (measured) response function correlates with a comparison function.

For this a generalized correlation function is calculated:

K (a, β, x _o , y _o , λ) = I Jv (αx + x _o , βy + y _o , λ) A (x, y _I λ) dx dy

-∞ -OO

α, ß are freely selectable scaling parameters, x ₀ , yo are freely selectable position parameters. The above equation is to be understood as meaning that the integration is performed over two coordinates, but possibly only over one coordinate. The values for V and A for variables that exceed the measuring range are set equal to 0.

The correlation function provides information about the extent to which the response function A (x, y, λ) with a comparison function V (αx + x _0, Py + y _0, λ) is correlated and how strongly this correlation changes when its variables to be changed, that is, how significant the correlation is.

The comparison function may, but does not have to, be identical to the intensity distribution I (x, y, λu) of the environmental influence or its underlying pattern function M (x, y, λu) or else the product of intensity distribution I (x, y, λu). and pattern function M (x, y, λu). The comparison function generally describes the expected or the desired property change of the surface by the marking. As expected, however, this property change has the characteristic pattern of the marking or the intensity distribution of the environmental influence.

If, for example, the marking exists in a reflection change of the surface due to irradiation with light, the comparison function is to be selected so that its xy dependence is the known xy dependence of the known location-dependent intensity distribution I (x, y, λu) or the underlying one Pattern function M (x, y, λu) or the product of intensity distribution I (x, y, λu) and pattern function M (x, y, λu) corresponds. The comparison function does not have to have any explicit wavelength dependence. The correlation function only reflects the desired, ie the change in the surface caused by the marking and effectively suppresses interferences such as statistical noise, sample inhomogeneities and influences of extraneous light. This results in a very high sensitivity.

A variant of the general correlation analysis is the Fourier analysis.

In one embodiment of the method according to the invention, the marking has a periodic pattern with a spatial frequency α. on. This marking can be produced by printing on the surface by means of a customary printing process. However, it can also be produced by exposure or general irradiation of the surface, the exposure or irradiation with a corresponding periodic intensity distribution I (x, y, λ) taking place with a spatial frequency α. A periodic intensity distribution can be generated by using a mask with a periodic transmission function T (x, y, λ) = M (x, y, λ). This can be, for example, a so-called barcode mask, for example a transparent film with a print of regularly (equidistantly) arranged (largely) nontransparent bars (so-called black / white barcode mask), or a template with a corresponding sequence of rectangular recesses. Instead of using a mask, an optical grating with a corresponding pattern function M (x, y, λ) can also be projected onto the surface.

By way of example, a method of correlation analysis for determining the correlation between the location-dependent intensity distribution I (x, y, λ) or the corresponding pattern function M (x, y, λ) of the marking and the response function A (x, y, λ) is described below , Methods of correlation analysis are known per se and have been described in detail in the literature. The invention is therefore not in the provision of such mathematical methods.

If the transmission function of the mask, which generates a specific intensity distribution, or the pattern function has a periodic structure, then particularly clear relationships result. For example, if you choose the transmission function

T (x, y, λ u) = ¹ Z ₂ (I + cos (α ₀ x)),

and photochemically generates the pattern on the surface of the fabric, it holds that V (x, y, λ) = I (x, y, λ) = T (x, y, λ): K (alpha, beta, x _o, y _o, λ) = J ^• (l + cos (OR *)) ^• A (x, y) dx

Thus, the correlation function is the real Fourier transformation of the response function except for a constant, α can thus be understood as spatial frequency. Further, K (α, β, Xo, yo, λ) shows a contribution caused by the irradiation only at the natural frequency O _{0 of} the mask. For all other spatial frequencies α ≠ α ₀ , the correlation function disappears. Thus, one obtains an infinitely high spatial frequency resolution αo / Δα.

In practice, however, it should be noted that due to the finite sample size X _max, the integration can not be performed from minus infinity to plus infinity. Furthermore, it does not measure continuously, but the response function is digitized with a limited number of nodes. The density of the interpolation points results in an upper limit for the still measurable spatial frequency. In contrast, the finite sample size results in a finite spatial frequency resolution power oto / Δα, which is given by α _o / Δα = α _o ^• x _ma χ-

This means that disturbances caused by statistical processes (signal noise) are less effectively suppressed than at infinitely high spatial frequency resolving power. In practice, however, it has been found that despite these limitations, the method according to the invention has a sensitivity that is more than a hundred times higher than that of a visual inspection.

From the pattern recognition by correlation analysis results in a very high sensitivity of the detection of the mark on the surface of the product. Thus, it is possible to detect visually imperceptible markings with high sensitivity and thus to enable an authenticity check of the goods.

The surfaces to be marked may consist of any materials, for example the surfaces of metals, plastics, wood, paint, paper or cardboard. The marking may be applied to the product itself, if it is suitable for the application of markings, or on its packaging. The term "goods" within the meaning of the invention therefore also includes the packaging of the goods.The goods to be marked can come from any sector, for example the products of the chemical and pharmaceutical industries, the mineral oil industry, the vehicle industry. and the supply industry, the textile and clothing industry, the toy industry, the food, beverage and stimulant industry, the electrical industry, the cosmetics and personal care industry, the products of mechanical and plant engineering, software, digital media and consumer electronics.

The invention is further illustrated by the following examples.

Examples

example 1

With the help of an exposure apparatus, an invisible barcode information was inscribed in a spruce wood panel as follows. For this purpose, a barcode pattern with a period length of 1 mm was produced on a film of the type AGFA-FiIm (type 3ZESP) with the aid of the Panherpro / 46 type exposure apparatus from Prepress. The 8 x 8 cm sheet was attached to the spruce board with all 4 corners for travel purposes, with the foil grid oriented perpendicular to the wood grain. Care was taken to ensure that the film lay as flat as possible on the smooth wooden surface and that the film could not move during the irradiation. The thus prepared wood panel was exposed to sunlight for 30 minutes with the sunlight falling approximately perpendicular to the sample surface.

After exposure, the foil grid was removed and the wood surface was visually inspected. There was no visual discernible change in the sample surface with the eye (no lattice visible).

After irradiation, the mesh foil was removed. The lattice film and wooden board (exposed side down) were placed on the object glass of an HP SCANJET 550 C scanner and scanned under the following conditions:

True Color (16.7 million colors) Resolution: 1200 dpi Contrast: medium Color: automatic Exposure: automatic

The R, G, B signals of the irradiated wood surface were then subjected to a one-dimensional Fourier transformation. The intensity measured by the scanner are denoted by S _j (k, m). Here, the subscript j denotes the R, G, B colors (red, green and blue). In contrast, the quantities k and m indicate the location where the intensity was measured. The direction indicated by k or m is referred to below as the image line or image column. With the help of the mathematical operation:

the power spectrum P _j (k ', m) was calculated for each image line. The power spectra thus obtained for each image line were averaged over all image columns:

ΣP _j (k ', m) all image lines Number of picture lines

In the examples shown, in each case the averaged power spectrum P _; (A: ') over the

Spatial frequency k 'plotted. Photochemical signals can be clearly recognized in the channels R, G, B in that a markedly increased intensity of the averaged power spectrum can be detected at the spatial frequency defined by the foil grid. The magnitude of this intensity in each channel is a measure of the visually imperceptible barcode information. The quantities plotted on the X-axis or Y-axis in FIGS. 1 and 2 are proportional to the spatial frequency OF or the intensity I of the averaged power spectrum.

The result of the one-dimensional Fourier transformation is shown in FIG.

The FT power spectrum of the grid film is shown in FIG.

FIG. 2 shows the dimensionless spatial frequency of the grating of FIG. 44. In this spatial frequency observed in Figure 2 in the blue channel a very high, green channel in the middle and in the blue channel a relatively small signal peak. This corresponds to a bar code in brown color far below the visibility limit. The Peak heights of the signals are plotted logarithmically to make small effects such as noise etc. more visible. The photochemically generated information could still be read after months of uniform exposure to daylight with the aid of the above-described evaluation method.

Example 2

Example 1 was repeated, but irradiated with an artificial exposure apparatus with an irradiance of 3 times the solar radiation intensity for 5 sec. Similar results were obtained as obtained in Example 1.

Example 3

With the help of an inkjet printer of the type HP 2000 C the program Powerpoint on blue background (EPSON special paper with the dimensions 9 x 11 cm) printed a visually imperceptible pattern with the following settings:

Red: 53 Color: 170

Blue: 53 Saturation: 153 Green: 205 Intensity: 129

The period of the grating was 1 / cm. The grid information was printed perpendicular to the print lines of the inkjet printer.

The pressure thus generated was scanned as described in Example 1. With the aid of the evaluation method described in Example 1, the result shown in FIG. 3 was obtained.

FIG. 3 shows the fundamental frequency as well as 2 harmonic overtones of the invisible barcode pattern. The effects are particularly pronounced in the absorption area of the blue pressure, ie in the red channel. The amplitudes R of the fundamental frequency and the two overtones are in the red channel: 420: 170: 80.

Claims

claims

1. A method for checking the authenticity of goods comprising the identification and identification of the goods in which one

(i) in a marking step on the surface of the goods, a marking in the form of a pattern with a pattern function M (x, y) brings up, caused by the marking a local change in the physically measurable properties of the surface of the product in the region of the marking and where the mark is imperceptible to the eye,

(Ii) detects in an identification step, the transmission, reflection or scattering of analysis radiation through the surface of the product as a function of the location coordinates (x, y) and the wavelength λ of the analysis radiation, thus determining a response function A (x, y, λ), which the intensity of the transmitted, reflected or scattered analysis radiation as a function of the location coordinates (x, y) and the wavelength λ, and by correlation analysis the correlation of the response function A (x, y, λ) with the known pattern function M (x, y), the label being detected by the correlation.

2. The method according to claim 1, characterized in that the mark is printed on the surface of the goods, wherein printing inks are used with minimal colorant content, which results in markings that are imperceptible to the eye.

3. The method according to claim 1, characterized in that one generates the marking on the surface of the product such that one of an environmental influence, which is suitable to change the physically measurable properties of the surface, with a specific, location-dependent intensity distribution I (x, y ), which corresponds to the pattern function M (x, y), is allowed to act on the surface.

4. The method according to claim 3, characterized in that the environmental influence is the action of radiation on the surface.

5. The method according to claim 4, characterized in that the label is generated photochemically.

6. The method according to any one of claims 3 to 5, characterized in that the intensity distribution I (x, y) is generated by the fact that the environmental influence through a mask, which corresponds to one of the intensity distribution I (x, y)

Transmission function T (x, y) has, act on the surface.

7. The method according to any one of claims 1 to 6, characterized in that the pattern is an irregular pattern.

8. The method according to any one of claims 1 to 6, characterized in that the pattern is a regular pattern with a spatial frequency α.

9. The method according to claim 8, characterized in that the correlation analysis is a Fourier analysis.

10. The method according to any one of claims 1 to 9, characterized in that one detects the reflection of the analysis light.

11. The method according to claim 10, characterized in that one uses a telecentric measuring optics in the detection.

12. The method according to any one of claims 1 to 9, characterized in that one detects the scattering of the analysis light.

13. The method according to claim 12, characterized in that one uses a confocal color measuring system during the detection.

14. The method according to any one of claims 1 to 13, characterized in that one determines the response function A (x, y, λ) with a digital Bildauswerteelektronik.

15. A method for labeling goods, comprising the labeling step (i) according to one of claims 1 to 8.

16. A method for identifying goods, comprising the identification step (ii) according to any one of claims 1 and 9 to 14.