RU140180U1 - MICRO-OPTICAL IMAGE FORMING SYSTEM FOR VISUAL AND INSTRUMENTAL CONTROL - Google Patents

Abstract

1. Micro-optical imaging system for visual and automated control, which is a flat phase optical element placed on a flat substrate, consisting of elementary regions R, up to 50 μm in size, i = l, 2, ... Ν; j = l, 2, ... Ν, where Ν is the number of partitions of the optical element into elementary regions along the coordinate axes, characterized in that each elementary region R contains a region Q filled with a fragment of a multi-gradation kinoform that forms asymmetric when the optical element is illuminated by laser radiation image for automated control, while the remaining part of each elementary region R is filled with diffraction gratings, which, when the optical element is illuminated with white light, form a visual image on This region of the optical elementa.2. The micro-optical system according to claim 1, characterized in that the Q region occupies an area within 15-50% of the area of each of the elementary regions R.3. Micro-optical system for the formation of visual images according to any one of claims 1 and 2, characterized in that it is configured to reflect light. Micro-optical system according to claims 1 and 2, characterized in that it is configured to partially reflect and partially transmit light. Micro-optical system for generating visual images according to any one of claims 1 to 4, characterized in that it is made in the form of a security label used to protect banknotes, securities, documents, plastic cards, bank payment cards, excise, identification, control marks, as well as various consumer goods from a fake.

Description

Declared as a useful model, the micro-optical imaging system for visual and instrumental control relates mainly to devices used to authenticate products and can be effectively used to protect banknotes, securities, documents, plastic cards from counterfeiting. Planar optical elements are now an integral part of the security documents, banknotes, plastic cards (van Reness, Rudolf L, Optical Document Security, 3 ^{rd ed. British Library Cataloguing in Publication} Data, 2005, ISBN 1-58053-258-6, van Renesse, Rudolf L, Optical Document Security, 2 ^nd ed. British Library Catalog in Publication Data, 1998, ISBN 0-89006-982-4). One of the main tasks is the development of optical security elements that can be used both for visual control and for automated instrumental authentication.

Closest to the claimed utility model in terms of features is the application for the invention "Method of protection and identification of optical security labels (options) and a device for its implementation" (prototype) (application EAPO No. 2011100415/26). The method of protection and identification of optical security labels described in the application for the invention is based on the fact that regions representing a multi-gradation kinoform, which when illuminated by laser radiation forms a latent image in the focal plane of the automated control device, are included in the protective flat optical element. Such images are called CLR (Covert Laser Readable) images. The detection system of the automated control device located in the focal plane registers the CLR image. The digitized image is processed by a microprocessor, which forms signs of control and verifies the authenticity of the optical security element.

The kinoform structure proposed in the prototype provides automated control that is invariant with respect to the shear of the device and its rotation, if the control is carried out in the region of a flat optical element consisting of a kinoform. The remaining area of the flat optical element in the prototype is responsible for the formation of the visual image. Automated control in this area is not possible.

The task to which the claimed utility model is directed is to create a micro-optical system with a higher level of protection against fakes and to simplify the automated control procedure. Another objective of the utility model is to maintain a standard level of costs for its manufacture.

At the same time, a technical result is achieved, which consists in increasing the reliability of protection against counterfeiting, in expanding the capabilities of automated control, and also in making it possible to use technologies for mass replication of protective optical elements.

The problem with the achievement of the specified technical result in the claimed microoptical imaging system for visual and automated control is solved by the fact that the microoptical system is a flat phase optical element placed on a flat substrate, consisting of elementary regions R _ij , up to 50 microns in size, i = 1, 2, ... N; j = 1, 2, ... N, where N is the number of partitions of the optical element into elementary regions along the coordinate axes. Each elementary region R _ij contains a region Q _ij filled with a fragment of a multi-gradation kinoform, which forms an asymmetric image for automated control when the optical element is illuminated by laser radiation, while the remaining part of each elementary region R _{ij is} filled with diffraction gratings that form white light when the optical element is illuminated visual image over the entire area of the optical element.

The micro-optical system for generating visual images can be performed so that the Q _ij regions occupy an area within 15-50% of the area of each of the elementary regions R _ij .

In the particular case, the micro-optical system for forming visual images is configured to reflect light.

The micro-optical system for forming visual images can be performed, if necessary, with the possibility of partial reflection and partial transmission of light.

If necessary, the micro-optical system for the formation of visual images is performed in the form of a security label used to protect banknotes, securities, documents, plastic cards, bank payment cards, excise, identification, control marks, as well as various consumer goods from counterfeiting.

The spot size of a laser imaging a latent CLR image is of the order of one millimeter. With automated control at any point in the microoptical system, at least a hundred regions Q _ij fall into the region of the laser spot. Thus, unlike the prototype, in the claimed utility model, automated control can be carried out at any point of the protective optical element. This fact is the main difference between the claimed utility model and the prototype.

Thus, the main differences of the claimed microoptical system from the prototype are as follows:

1. The microoptical system has a facet structure, in which the optical element is divided into elementary regions smaller than 50 microns in size, in each of which fragments of kinoforms and diffraction gratings are located.

2. The structure of the micro-optical system allows you to create a visual image that is visible to the observer over the entire area of the optical element.

3. The micro-optical system allows automated control at any point of the optical element, which greatly simplifies the automated control procedure.

4. The micro-optical system is more secure compared to the prototype, since a large number of Q _ij regions up to 50 microns in size are involved in the formation of CLR images.

The essence of the utility model is illustrated by the image, where in Fig.1 shows a fragment of a micro-optical system according to the claimed utility model, in Fig. Figure 2 shows a fragment of the microrelief of the kinoform forming CLR. the image in FIG. 3 shows an example of a symmetrical microrelief; in FIG. 4 shows a fragment of an asymmetric microrelief; in FIG. 5 shows an example of an asymmetric CLR image formed by a multi-gradation kinoform; FIG. 6 is an optical diagram for generating CLR images; FIG. 7 is an example of an image visible to an observer when illuminated with a micro-optical system in white light.

The micro-optical system claimed in this technical solution is a flat phase optical element, a fragment of which is shown in FIG. 1. The optical element consists of elementary regions R _ij , up to 50 microns in size, indicated in FIG. 1 by the number 1. Here i = 1, 2, ... N; j = 1, 2, ... N, where N is the number of partitions of the optical element into elementary regions along the coordinate axes. Each elementary region R _ij contains a region Q _ij , indicated in FIG. 1 by the number 2. The regions Q _{ij are} filled with fragments of the multi-gradation kinoform 3, which forms an asymmetric image for instrumental automated control when the optical element is illuminated by laser radiation. The laser spot size is of the order of one millimeter. At least hundreds of elementary regions Q _ij fall inside the laser spot, which, unlike the prototype, provides the possibility of automated control at any point in the microoptical system.

In FIG. Figure 2 shows a fragment of a kinoform, about 30 by 30 microns in size, forming a CLR. picture. The microrelief depth is proportional to the darkening at each point in FIG. 2. Two types of microrelief of planar phase optical elements are distinguished: symmetrical, as shown in FIG. 3, and asymmetric, as shown in FIG. 4. For the formation of hidden images, you can use binary kinoform. The binary kinoform has a symmetrical microrelief. Such optical elements (with a symmetrical microrelief) can only form images that are symmetrical about zero order diffraction. For the formation of asymmetric images, multi-gradation kinoforms are used (A.V. Goncharsky, A.A. Goncharsky Computer Optics & Computer Holography Moscow University Press 2004).

The method of forming latent images used in this invention is called kinoforms. The kinoform as an optical element was presented in (LB Lesem, PM Hirsch, JAJr. Jordan, The kinoform: a new wavefront reconstruction device, IBM J. Res. Dev., 13 (1969), 105-155). The claimed utility model uses multi-gradation kinoforms to form CLR images. Multi-gradation kinoform forms a given image, but unlike thin holograms recorded by recording an interference pattern, multi-gradation kinoform forms only one image at a given wavelength, and all the light incident on it diffracts by one diffraction order. Thus, multi-gradation kinoform has maximum theoretical efficiency in the formation of arbitrary images. The task of calculating the microrelief of multi-gradation kinoforms relates to complex inverse problems. Algorithms exist that make it possible to calculate the microrelief of a multi-gradation kinoform from a given image in the focal plane. (AV Goncharsky, AA Goncharsky Computer Optics & Computer Holography Moscow University Press 2004). Fragments of the kinoform located in the regions Q _ij form the same CLR image in the focal plane. An example of such an image is shown in FIG. 5. A bright dot in the center of FIG. 5 corresponds to the zeroth diffraction order.

In FIG. Figure 6 shows the optical scheme for the formation of CLR images during instrumental control. Visualization of CLR images is carried out using laser radiation. The laser beam 4 is incident perpendicular to the optical element 5, forming an image in the focal plane 6 of the CLR, a fragment of which is indicated by the number 7.

For the manufacture of the original micro-optical system, electron beam lithography is used. This technology is high-tech and well protected from fakes. The inventive utility model allows for mass replication of optical elements, because for their manufacture, you can use the standard technology for replicating holograms, including in the form of hot stamping foils. In practice, the manufacturing process of a flat optical element includes the following stages: calculation of the parameters and structure of the microrelief of the flat optical elements forming protective images, the formation of the calculated microrelief on a flat medium using electron beam lithography. The following is the standard technology for the mass replication of holograms, namely, electroforming, rolling, applying adhesive layers, cutting, etc. The possibility of using standard holographic equipment for mass replication makes it possible to produce microoptical protective systems declared as a utility model at a low price.

As an example of the implementation of the utility model, a micro-optical system was manufactured, the visual image of which, when illuminated with white light, is shown in FIG. 7.

As the CLR image for instrumental control, the image shown in FIG. 5. A microstructure fragment of a multi-gradation kinoform is shown in FIG. 2. The CLR image formed in coherent light is asymmetric. The area of the Q _ij regions was 20 percent of the area of the elementary regions R _ij .

The microrelief of flat optical elements was recorded using electron beam lithography (Carl Zeiss ZBA-21 electronic lithograph) on plates with an electronic resist. The resolution of the electronic lithograph is 0.1 microns. The microrelief depth of the optical security element ranged from 100 to 300 nm. The size of the optical security element was 20 × 34 mm. After fabrication of plates with an electronic resist after metallization using electroplating, the master of the matrix of micro-optical systems was made. After the standard holographic animation procedure, multiplied master matrices were made, from which working matrices for rolling were made. Holographic foil was made using standard James River rolling equipment. After applying the adhesive layers, samples of optical protective elements were made. The thickness of the optical protective elements was 19 microns.

The fabricated samples demonstrated the possibility of both visual and automated instrumental control of the micro-optical system. The micro-optical system presented in the utility model can be effectively used to protect banknotes, certificates, checks, plastic cards.

Claims (5)

1. Micro-optical imaging system for visual and automated control, which is a flat phase optical element placed on a flat substrate, consisting of elementary regions R _ij , up to 50 μm in size, i = l, 2, ... Ν; j = l, 2, ... Ν, where Ν is the number of partitions of the optical element into elementary regions along the coordinate axes, characterized in that each elementary region R _ij contains a region Q _ij filled with a fragment of a multi-gradation kinoform that forms when the optical element is illuminated laser radiation asymmetrical picture for automated control, with the remaining portion of each elementary region R _ij filled diffraction gratings, which when illuminated by white light of the optical element form a visual pICTURE s on the entire region of the optical element. 2. The micro-optical system according to claim 1, characterized in that the region Q _ij occupies an area within 15-50% of the area of each of the elementary regions R _ij . 3. Micro-optical system for the formation of visual images according to any one of claims 1 and 2, characterized in that it is configured to reflect light. 4. Micro-optical system according to claims 1 and 2, characterized in that it is configured to partially reflect and partially transmit light. 5. The micro-optical system for generating visual images according to any one of claims 1 to 4, characterized in that it is made in the form of a security mark used to protect banknotes, securities, documents, plastic cards, bank payment cards, excise, identification, control marks, as well as various consumer goods from counterfeiting.

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