RU2329155C2 - Method of object protection against forgery and method of authenticity control of object protected against forgery - Google Patents

Abstract

FIELD: technological processes.

SUBSTANCE: method of object protection against forgery includes application of information identifying mark to the surface of protected object by means of glue layer, in composition of which light-sensitive protein bacteriorhodopsin is introduced. Information identifying mark or its part is made transparent, and corresponding portion of protected object surface is made transparent or with mirror reflecting coating. During monitoring of object authenticity light-sensitive element that contains bacteriorhodopsin is illuminated, by means of two sources of light with lengths of waves, accordingly, in band of main and intermediate conditions of bacteriorhodopsin absorption.

EFFECT: invention allows to increase reliability of protection against forgery and monitoring of valuable documents and items.

3 cl, 4 dwg

Description

The invention relates to methods for identifying an object and can be used to increase the reliability of protection against counterfeiting and authenticity control of various valuable documents and products.

The prior art method of protecting an object from counterfeiting by applying an information identifying tag with its fixation by means of an adhesive layer to the surface of the protected object (RU 2035315 C1, B44F 1/12, 1995; RU 2077071 C1, G07D 5/00, 1997; FR 2331455, G07D 7/00, 1977; DE 3628353, B44F 1/12, 1988). The main disadvantage of this method is the possibility of substituting an identifying information label, which, as a rule, is used as a hologram, which reduces the reliability of protection against falsification of the object itself.

There is also a known method of authenticating an object, including irradiation — illumination of a photosensitive element by a light source in a normalized wavelength range, reception of light energy by a photosensor, and comparison with a reference value (RU 2123722 C1, G07D 7/06, 1998; RU 2115169 C1, G07D 7/12 , 1998). However, in the process of operation of the controlled object, its photosensitive element in some cases can change its optical properties, which when compared with the standard leads to an incorrect result.

The invention is aimed at improving the reliability of protection of an object from forgery and control of its authenticity.

The solution to this problem is ensured by the fact that in the method of protecting an object from counterfeiting by applying an information identifying tag with its fixation by means of an adhesive layer to the surface of the protected object, according to the invention, a photosensitive element — bacteriorhodopsin protein — is introduced into the adhesive layer, while the information identifying label or part thereof perform transparent, and the corresponding surface area of the protected object is performed transparent or with a mirror-reflective coating.

In addition, in the method for verifying the authenticity of a fake-protected object equipped with a photosensitive element, including illuminating the photosensitive element with a light source in a normalized wavelength range, receiving light energy and comparing with a reference value, according to the invention, a transparent adhesive layer containing bacteriorhodopsin is used as a photosensitive element, placed between the object and the additional information identifying tag, which is illuminated using two and light sources with wavelengths, respectively, in the absorption band of the ground and intermediate states of bacteriorhodopsin, while the reference energy is the light energy received by light or reflection from one light source with a wavelength in the absorption band of the ground or intermediate states of bacteriorhodopsin, and register its change in subsequent simultaneous illumination with a second light source having a wavelength, respectively, in the absorption band of an intermediate or ground state Nia bacteriorhodopsin.

In this case, the illumination of the photosensitive element is carried out by a light source with a maximum radiation at a wavelength of about 570 nm for the absorption band of the ground state of bacteriorhodopsin BR570 and a light source with a maximum radiation at a wavelength of about 410 nm for the absorption band of the intermediate state of bacteriorhodopsin M412 at a radiation power density of 0.1 ÷ 2.0 mW / cm ² .

Introduction of bacteriorhodopsin, the photosensitive halobacterium protein Halobacterium salenarum, into the cell membranes (purple membranes) of which it is embedded (M.V. GUSEV, L.A. MINEEVA, MICROBIOLOGY, PUBLISHING HOUSE OF MOSCOW UNIVERSITY, 1992, chap. 18), into the adhesive layer by means of which an information identification tag in the form of a hologram, company label or similar sticker is attached to the protected object, provides with technological simplicity a second additional level of protection, since photochromic properties Bacteriorhodopsin determine the transmission value of the adhesive layer when it is illuminated using two light sources with wavelengths, respectively, in the absorption band of the ground and intermediate states of bacteriorhodopsin. At the same time, the reliability of the object’s authenticity control is achieved by simple technical means due to the use of the light energy taken as a reference or reflected from a single light source with a wavelength in the absorption band of the main or intermediate state of bacteriorhodopsin, and registration of the change in the light energy value accepted luminosity or reflection under subsequent simultaneous illumination with a second light source having a wavelength, respectively, in a strip along absorption of the intermediate or ground state of bacteriorhodopsin, which does not require prior calibration — determination of the photochromic parameters of the monitored photosensitive element and does not depend on their possible change.

Figure 1 and 2 presents a control circuit of the authenticity of the object with the reception of light energy in the light; figure 3 and 4 is a diagram of the authentication of the object with the reception of light energy for reflection.

The control circuit includes a protected object 1, information identification tag 2, which is attached to the surface of object 1 by means of a transparent adhesive layer 3 containing bacteriorhodopsin of strain ET1001, light source 4 with a wavelength in the absorption band of the main BR570 state of bacteriorhodopsin (LED with a maximum radiation at a wavelength near λ ₁ = 570 nm), a light source 5 with a wavelength in the absorption band of the intermediate M412 state (LED with a radiation maximum at a wavelength near λ ₂ = 410 nm), photodetector 6 with register 7. At the same time, the information identifying mark 2 is made transparent, and the corresponding portion 8 of the surface of the protected object 1 is made transparent (Fig. 1, 2) or with a mirror-reflective coating 9 (Fig. 3, 4). It is possible to perform information identifying tags 2 with a transparent section 10 or with a through window-hole 11 (Figure 2, Figure 3). Alternatively, if an informational identification tag 2 is made of an opaque material, a mirror-reflective coating similar to coating 9 is applied to its surface facing the adhesive layer 3, and the corresponding surface area of the protected object 1 is made transparent or in the form of a through-hole (not shown).

The claimed method is implemented as follows.

On the surface of the transparent section 8 of the protected object 1 (it is possible to make this section in the form of a through-hole) or on the mirror-reflecting coating 9 by means of a transparent adhesive layer 3, into the adhesive mass of which bacteriorhodopsin is introduced in a ratio of 10: 1 ÷ 100: 1, transparent information identification tag 2, for example, in the form of a hologram, company label or similar sticker with an optical effect, providing the first low level of protection controlled by the naked eye. Moreover, any water-soluble adhesives, for example, organic, such as casein, dextrin, gum arabic, polyvinyl alcohol based adhesives, silicate adhesives, as well as other adhesives that do not contain solvents harmful to bacteriorhodopsin, can be used as adhesives for the adhesive mass of adhesive layer 3 additives (for example, using saturated hydrocarbons as solvents: hexane, heptane, etc.), in which bacteriorhodopsin fully retains all its photochromic properties, significantly changing the value of letting the adhesive layer 3 in the absorption band when illuminated with visible light. The second high level of protection due to the presence of bacteriorhodopsin in the adhesive layer is controlled using two light sources 4 and 5 with wavelengths, respectively, in the absorption band of the ground and intermediate states of bacteriorhodopsin (λ ₁ = 570 nm and λ ₂ = 410 nm) changing the transmission value of the adhesive layer 3.

Example 1

The transparent section 8 of the protected object 1 (Fig. 1) with the adhesive layer 3 containing bacteriorhodopsin and the transparent information identification tag 2 illuminate completely through the light source 4 (LED with a wavelength of λ ₁ = 570 nm) in the absorption band of the main BR570 state of bacteriorhodopsin. Passed through the adhesive layer 3, the flux of light energy enters the photodetector 6, the signal from which is amplified and recorded by the recorder 7 as a reference. Then, two light sources are illuminated simultaneously: a light source 4 will illuminate with additional illumination by a light source 5 (an LED with a wavelength of λ ₂ = 410 nm) in the absorption band of the intermediate M412 state of bacteriorhodopsin, the signal from the photodetector 6 is recorded by the recorder 7 and the obtained value is compared with the reference previously registered. With a radiation power density of 0.1 ÷ 2.0 mW / cm ^{2, a} change - a decrease in the transmission of the adhesive layer 3 (the relative difference between the first and second recorded light energy values) is 5 ÷ 8%, which makes it possible to simply, reliably and unambiguously determine the authenticity of the object 1 and distinguish it from a fake.

Example 2

The transparent portion 8 of the protected object 1 (FIG. 2) with the adhesive layer 3 containing bacteriorhodopsin and the transparent portion 10 of the information identification tag 2 illuminate completely through the light source 5 (LED with a wavelength of λ ₂ = 412 nm) in the absorption band of the intermediate M412 state bacteriorhodopsin. Passed through the adhesive layer 3, the flux of light energy enters the photodetector 6, the signal from which is amplified and recorded by the recorder 7 as a reference. Then, two light sources are illuminated simultaneously: a light source 5 will illuminate with additional illumination by a light source 4 (an LED with a wavelength of λ ₁ = 570 nm) in the absorption band of the main BR570 state of bacteriorhodopsin, the signal from the photodetector 6 is recorded by the recorder 7, and the obtained value is compared with the reference previously registered. With a radiation power density of 0.1 ÷ 2.0 mW / cm ^{2, a} change - a decrease in the transmission of the adhesive layer 3 (the relative difference between the first and second recorded light energy values) is 5 ÷ 8%, which makes it possible to simply, reliably and unambiguously determine the authenticity of the object 1 and distinguish it from a fake.

Example 3

The area of the protected object 1 with a mirror-reflecting coating 9 (Fig. 3) and an adhesive layer 3 containing bacteriorhodopsin, is illuminated through the through-hole 11 of the information identification mark 2 in an oblique incidence mode using a light source 4 (LED with a wavelength of λ ₁ = 570 nm) in the absorption band of the main BR570 state of bacteriorhodopsin. Passed through the adhesive layer 3 and reflected by a mirror-reflective coating 9, the flow of light energy enters the photodetector 6, the signal from which is amplified and recorded by the recorder 7 as a reference. Then, two light sources are illuminated simultaneously: a light source 4 in an oblique incidence mode with additional illumination by a light source 5 (an LED with a wavelength of λ ₂ = 410 nm) in the absorption band of the intermediate M412 state of bacteriorhodopsin, the signal from the photodetector 6 is recorded by the recorder 7, and the received signal is compared value with a reference previously registered. With a radiation power density of 0.1 ÷ 2.0 mW / cm ^{2, a} change - a decrease in the transmission of the adhesive layer 3 (the relative difference between the first and second recorded light energy values) is 4 ÷ 7%, which makes it possible to simply, reliably and unambiguously determine the authenticity of the object 1 and distinguish it from a fake.

Example 4

The area of the protected object 1 with a mirror-reflective coating 9 (Figure 4) and an adhesive layer 3 containing bacteriorhodopsin, and a transparent information identification tag 2 are illuminated in an oblique incidence mode using a light source 5 (LED with a wavelength of λ ₂ = 410 nm) in a strip absorption of the intermediate M412 state of bacteriorhodopsin. Passed through the adhesive layer 3 and reflected by a mirror-reflective coating 9, the flow of light energy enters the photodetector 6, the signal from which is amplified and recorded by the recorder 7 as a reference. Then, two light sources are illuminated simultaneously: a light source 4 in an oblique incidence mode with additional illumination by a light source 5 (an LED with a wavelength of λ ₁ = 570 nm) in the absorption band of the main BR570 state of bacteriorhodopsin, the signal from the photodetector 6 is recorded by the recorder 7, and the received signal is compared value with a reference previously registered. With a radiation power density of 0.1 ÷ 2.0 mW / cm ^{2, a} change - a decrease in the transmission of the adhesive layer 3 (the relative difference between the first and second recorded light energy values) is 4 ÷ 7%, which makes it possible to simply, reliably and unambiguously determine the authenticity of the object 1 and distinguish it from a fake.

Claims (3)

1. A method of protecting an object from counterfeiting by applying an information identifying tag with its fixation by means of an adhesive layer to the surface of the protected object, characterized in that the photosensitive bacteriorhodopsin protein is introduced into the adhesive layer, while the information identifying label or part thereof is transparent, and the corresponding section the surface of the protected object is transparent or with a mirror-reflective coating. 2. A method for verifying the authenticity of a fake-protected object, including illuminating a photosensitive element with a light source in a normalized wavelength range, receiving light energy and comparing with a reference value, characterized in that they illuminate a photosensitive element containing bacteriorhodopsin using two light sources with wavelengths accordingly, in the absorption band of the ground and intermediate states of bacteriorhodopsin, the value of light energy being used as a reference oh naprosvet or reflection from a single light source with a wavelength in the absorption band of the ground state of the bacteriorhodopsin or intermediate, and its variation is recorded in the subsequent simultaneous illumination with the second light source having a wavelength respectively in the absorption band of the intermediate or the ground state of the bacteriorhodopsin. 3. The method of authenticating an object according to claim 2, characterized in that the light-sensitive element is illuminated by a light source with a maximum radiation at a wavelength of about 570 nm for the absorption band of the ground state of BR570 bacteriorhodopsin and a light source with a maximum radiation at a wavelength of about 410 nm for the absorption band of the intermediate state of bacteriorhodopsin M412 at a radiation power density of 0.1 ÷ 2.0 mW / cm ² .

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