RU2222433C1 - Method for manufacture of printing matter with main and latent images - Google Patents

Abstract

FIELD: printing arts. SUBSTANCE: the latent image is transformed to a digital hologram in the system of production of the Fourier hologram with a reference point source and a randomized phase of object radiation, its image is obtained and the matter is printed, changing the mutual position of the main image and the image of the hologram from impression to impression. In case of a multicolored latent image its color separation is performed, holograms are calculated through the respective color channels in the conditions of coinciding coordinates of the reference sources and phase of object radiations, and a multicolored hologram is obtained. EFFECT: enhanced degree of protection of printing matter against forgery at a simplified procedure of restoration of the latent image, enhanced creative possibilities in the design of printing matter. 2 cl, 7 dwg

Description

Protection against counterfeiting of printing products, especially in connection with the development of copying technology, is constantly being improved. One of the areas in the field of protective technologies is the use of holography theory and practice in printing. It is well known to pair optical holograms with printing products by means of stickers or moldings. Holograms are applied to labels, excise stamps, packaging, securities, etc. As a rule, optical holograms used in printing are so-called rainbow holograms that allow reproducing a color 3D image in natural light (see, for example, P. Hariharan, "Optical Holography: principles, techniques and applications", 2 ^nd ed. Cambridge University Press, New York, 1996, p. 131). Such holograms adorn printing products, and their very existence until recently served as satisfactory protection due to the novelty and non-proliferation of rainbow hologram technology and technique. To date, the situation has changed, the market has integrated equipment for an optical holographic laboratory, including rolled hologram replication machines. Thus, the reproduction of any hologram and its mass production is quite easily feasible.

To increase security, a classical flat hologram of a diffusely lit subject is often included in the composition of the rainbow hologram (see, for example, R. Koliere, K. Burkhart, L. Lin, "Optical holography", "Mir", M., 1973, p. 222 ) The object itself is not observable under natural illumination of the hologram; its image is hidden and reconstructed under laser illumination. Such a hologram is easily reproducible due to the aforementioned situation with the prevalence of holographic technology, and its presence cannot be considered as an element of design, because when localized, it represents a dull spot about a millimeter in size, and its registration on the area of the main hologram reduces the brightness and contrast of the visually observed image. In addition, the disadvantages of this method include the need to use at the stage of recovery of the latent image from such holograms of special optical devices with sources of coherent radiation.

With the proposed solution, this method coincides upon the application of the holographic principles of forming a latent image and introducing a hologram image along with the main image in printing products.

There is also a known method of manufacturing printed products with a basic and latent image, which consists in converting the latent image into a digital hologram in the scheme for obtaining a Fourier hologram with a reference point source and a randomized phase of subject radiation (P. Hariharan, "Optical Holography: principles, techniques and applications", 2 ^nd ed, Cambridge University Press, New York, 1996, p. 171). The advantage of this method is the ease of restoring the latent image by introducing the image of the print into the computer and applying the inverse Fourier transform to it using widely used programs, for example, the Mathcad 2000 Professional program. In addition, the visual observability of the holographic structure can be used for product design purposes, for example, for decorating the background, spot elements, etc. The disadvantage of this method from the point of view of protecting printed products from counterfeiting is the triviality of copying a single print and its subsequent replication.

This method coincides with the proposed solution according to the following essential features: the conversion of the latent image into a digital hologram in the scheme for obtaining a Fourier hologram with a reference point source and a randomized phase of subject radiation, obtaining a hologram image and printing products.

In the aggregate of essential features, the latter method is closest to the proposed method and is selected as a prototype.

SUMMARY OF THE INVENTION

The proposed method for the manufacture of printed products with the main and latent image is that the latent image is converted to a digital hologram in the scheme for obtaining a Fourier hologram with a reference point source and a randomized phase of the subject radiation, an image of a hologram is produced and the product is printed, and the image of the hologram and the main image when shifting relative to each other when printing, the amount of shift varies from print to print.

The proposed method differs from the prototype in that the image of the hologram and the main image is shifted when printing relative to each other when the amount of shift varies from print to print.

This difference provides an increase in the degree of security of printing products from counterfeiting due to the individualization of each print, and the quality and location of the restored image in the observation field does not depend on the amount of shift, i.e. reproduction identity from non-identical prints is provided. The latter is a consequence of the well-known property of flat holograms to leave the reconstructed image stationary while moving the hologram itself (see, for example, R. Koliere, K. Burkhart, L. Lin, Optical Holography, Mir, M., 1973, p. 245 ) Direct copying of an individual print and its printing duplication will lead to identical prints, which will indicate a fake.

In development of this method, a method is proposed in which color separation of the hidden image is additionally performed, holograms for each color are calculated under the conditions of matching coordinates of the reference sources and different realizations of the randomization of the phase of the subject radiation, and corresponding images are obtained. When implementing this method, different holograms have diverging spectrum structures due to different realizations of the randomization of the phases of the subject radiation, which makes it possible to multicolor print images of holograms and, as a result, restore the latent image in color. The proposed method further increases the degree of security and expands creative possibilities in the development of product design using complex multi-color structures.

The essence of the proposed method is illustrated by drawings, where in figures 1 and 2 are respectively examples of the main image, in the General case, multicolor, and hidden black and white. The frame (figure 1) shows the actual dimensions of the print.

Figure 3 shows the result of converting the hidden negative image (figure 2) into an image of a hologram calculated in the scheme for obtaining a Fourier hologram with a reference point source and a diffuse diffuser randomizing the phase of the subject radiation.

Figure 4 shows a topographic background composed of the holograms of figure 3 without breaking the continuity at the joints.

Fig. 5 shows a page of 210x297 mm format, where the background of Fig. 4 is sealed with the main images of Fig. 1 so that the distances between the main images are not multiples of the hologram repetition period against the background, which ensures that the arrangement of the main images with respect to the background pattern is not identical.

In Fig.6 presents the result of scanning a separate print obtained from one of the areas with the main image of Fig.5, and Fig.7 is a recovered latent image from it. Image restoration is calculated using the inverse Fourier transform applied to the image of the impression entered into the computer during scanning.

When a color image is hidden, it is color-separated, for example, according to the primary colors of the RGB space, and in each of the three color channels, a hologram is calculated using the same algorithm as a hologram of a black-and-white image. In the calculation, the coordinates of the reference sources for all channels are chosen coincident, but the diffuse diffusers are changed, i.e. the implementation of a random uniform distribution of the phases of the object radiation over the channels differ from each other. As a result of combining the color channels, a multi-color hologram is obtained, a holographic background is created and its main images are sealed with the same image as in the case of a single-color hologram. To restore the color latent image, a separate print is scanned in color, the scanned file is color-separated, the inverse Fourier transform is applied to each color channel, and a color image is obtained when color channels are combined.

List of figures

Figure 1 The main image.

Figure 2 Hidden black and white image.

Figure 3 Hologram hidden black and white image.

Figure 4 Holographic background of the black and white latent image.

Fig. 5 Capturing the background of Fig. 4 by main images.

6 Scanned print.

7. Restored Hidden Black and White Image

The possibility of carrying out the invention is illustrated by a specific example.

Let you want to print a label measuring 60x60 mm with the main image shown in figure 1. As the hidden image, we select the black and white image shown in figure 2. Images were created in Adobe Photoshop 4.0 in BMP format on a field of 512x512 pixels.

The hidden image is inverted (converted to negative), translated into the Mathcad 2000 Professional program using the READBMP function. The corresponding square numerical matrix of size 512x512 is denoted by A, its elements are a, j, where i = 0 ... 511, j = 0 ... 511.

Using the random number generation function with a uniform distribution in the interval 0-2 π- - rnd (2π) - a square matrix B = rn (2π) is constructed, a complex-valued matrix C with elements c _iJ = exp (kb _iJ ), where k - the imaginary unit, and the matrix D, as an element-wise product of the matrices A and C: d _iJ = a _iJ C _iJ .

The reference point source is introduced by assigning to some element of the matrix D a value selected based on the desired brightness and contrast of the hologram obtained in the future. In this example, the element d _{2i5, 2i5 is} assigned the value 10 ⁴ . Using the CFFT function of the fast two-dimensional Fourier transform, we find the complex-valued Fourier transform E of the matrix D: E = CFFT (D), which is converted to a normalized image of a hologram according to the algorithm:

Moreover, the matrix E has the same dimension as the matrix A, and the operations of finding the module and squaring are applied elementwise. The denominator is the value of the maximum matrix element / E / ² .

The image of the hologram G is presented in figure 3. In Adobe Photoshop 4.0, this image is multiplied without breaking continuity at the joints. Figure 4 shows the holographic background constructed in this way with a size of 1536x2048 pixels (respectively 180x240 mm). Its color tone can be matched by conventional means of the program Adobe Photoshop 4.0.

This construction background is doubly periodic with a period of 512 pixels, which implies that the main image can occupy 512 ² = 262144 different positions relative to the background. This is the possible volume of circulation of non-identical labels in the considered specific example of the implementation of the proposed method.

Figure 5 shows an example of capturing a page of 210x297 mm format with basic images on a holographic background of 1536x2048 pixels. The layout of the main images is designed so that the vertical and horizontal distances between them are not a multiple of 512 pixels. The non-identity of the prints is obvious by the location of the main image relative to the background image.

The recovery of the latent image is carried out by entering a separate print image into the computer using a scanner (Fig.6), translating the scanned file into the Mathcad 2000 Professional program using the READBMP function and applying the inverse fast Fourier transform ICFFT function. 7 shows the result of recovery.

In the case of a color hidden image created in Adobe Photoshop 4.0, translation into Mathcad 2000 Professional is performed by the three functions READ_RED, READ_GREEN, READ_BLUE, which perform color separation of the color image. The corresponding matrices are denoted by Al, A2, A3. Then, using the random number generation function with a uniform distribution in the interval 0-2 π-rnd (2π), three realizations of square matrices of type B = rnd (2π) are constructed: Bl, B2, B3, complex-valued matrices of type C: C1, C2 , C3 and matrices of type D: Dl, D2, D3.

After the Fourier transform in each color channel and the corresponding normalization, three matrixes of holograms of type G are obtained: Gl, G2, G3. By combining channels with Mathcad 2000 Professional, you get a multi-color hologram. This hologram is multiplied without joints in the program Adobe Photoshop 4.0, filling in the required area with a holographic background, page layout with prints and production printing are performed.

The hidden color image is restored by entering the print image into the computer when scanning in color, color separation, applying the inverse Fourier transform for each color channel and combining the channels.

To implement the proposed method, a desktop publishing house with the following hardware and software is sufficient:

- computer IBM PC Pentium II-450.128 MB RAM,

- SyncMaster 700ift monitor,

- scanner Helwlett Packard ScanJet 5200C,

- Epson Stylus Photo 1200 printer,

- computer mathematics system Mathcad 2000 Professional,

- image editing program Adobe Photoshop 4.0.

Claims (2)

1. A method of manufacturing a printed product with a main and latent image, namely, that the latent image is converted into a digital hologram in the scheme for obtaining a Fourier hologram with a reference point source and a randomized phase of objective radiation, an image of a hologram is produced and a product is printed, characterized in that the image of the hologram and the main image are shifted when printing relative to each other, and the amount of shift is changed from print to print. 2. The method according to claim 1, characterized in that the color separation of the hidden image is performed, holograms for each color are calculated under the conditions of matching coordinates of the reference sources and different realizations of the randomization of the phase of the subject radiation, and corresponding images are obtained.

Images