EP1670647B1 - Diffractive security element comprising a half-tone picture - Google Patents

Abstract

A diffractive security element has a half-tone image comprising diffractive structures in a reflection layer, which are embedded in a layer composite between a transparent embossing layer and a protective lacquer layer. The half-tone image is divided into image elements of at least one dimension less than 1 mm, wherein the surface of each image element is divided up into a background field and an image element pattern. The proportion of the image element pattern to the surface of the image element determines the surface brightness of the half-tone image at the location of the image element. The background field has a first diffractive structure from which the image element pattern differs by its light-modifying effect. Pattern strips of a width of up to 0.3 mm additionally extend over the surface of the half-tone image. The pattern strips occupy a small proportion of the surface of the background fields and/or the image element patterns and produce coloured strips on the half-tone image.

Description

The invention relates to a diffractive security element with a halftone image according to the preamble of claim 1.

Such security elements are used for the authentication of documents, banknotes, ID cards, valuable items of all kinds, etc., since they are difficult to duplicate, though easily verifiable. The security element is usually glued to the object to be certified.

From EP-A 0 105 099 it is known to construct a graphically designed security pattern from diffractive picture elements in a mosaic-like manner. The security pattern changes appearance when the viewer tilts the security pattern and / or rotates the security pattern in its plane.

EP-A-0,330,738 describes security patterns that have diffractive surface portions smaller than 0.3 mm, arranged singly or in a row in the structure of the security pattern. In particular, the surface parts form lettering with a height of less than 0.3 mm in height. The shape of the surface parts or the letters can only be recognized by means of a good magnifying glass.

It is also known from EP-A-0 375 833 to house in a security element a plurality of diffractive security patterns composed of pixels, wherein each of the security patterns is visible to the naked eye under a predetermined orientation in the normal reading distance. Each security pattern is divided into pixels of the grid given by the security element. The grid of the security element is subdivided into diffractive field shares according to the number of security patterns. In each grid, the pixels of the save patterns associated with the grid occupy their predetermined field portion.
DE-OS 1 957 475 and CH 653 782 disclose a further family of diffraction-optically active, microscopically fine relief structures under the name Kinoform. The relief structure of the kinoform deflects light into a predetermined solid angle. Only when the kinoform is illuminated with substantially coherent light can the information stored in the kinoform be made visible on a screen. The Kinoform scatters white light or Daylight in the solid angle predefined by the kinoform, but outside the solid angle, the kinoform surface appears dark gray.

The diffractive security patterns are enclosed in a composite layer of plastics, which is designed for attachment to an object. US Pat. No. 4,856,857 describes various embodiments of the layer composite and lists the suitable materials.

On the other hand, it is known from US Pat. No. 6,198,545 to form halftone images produced by printing technology from pixels with picture elements or characters, wherein the black component in the otherwise white pixel background is chosen so that the observer within the viewing distance of 30 cm to 1 m Halftone image and only on closer inspection, in the next distance or with the magnifying glass, the picture elements or signs can recognize. This image synthesis technique is known as "artistic screening". Good copies of halftone images without artistic screening are easy to produce due to the constantly improved resolution in the copying technique.

The invention has for its object to provide a diffractive security element that shows a halftone image and is difficult to imitate or copy.

The above object is achieved by the features specified in the characterizing part of claim 1 according to the invention. Advantageous embodiments of the invention will become apparent from the dependent claims.

The idea of the invention is to produce a diffractive security element having at least two distinct recognizable patterns, one pattern being a halftone image visually recognizable at a viewing distance of 30 cm to 1 m, composed of a plurality of pixel patterns. The picture element patterns are arranged on a background and cover locally, eg in a pixel, a portion of the background predetermined by the local area brightness in the halftone image. Both the background areas and the areas of the pixel patterns are optically active elements such as holograms, diffraction gratings, matte structures, specular surfaces, etc., with the optically effective elements differing in the areas of the pixel patterns and the background in the diffractive behavior. The pixel patterns in the halftone image are only for viewing at a reading distance less than 30 cm with or without aids, eg magnifying glass, recognizable. In another embodiment of the security element, pattern strips extending over the area of the halftone image as further patterns extend to 25 μm wide. The straight and / or curved pattern strips form a background pattern, such as guilloches, pictograms, etc. In the areas of the pattern strips, line elements are arranged on the background. The area fraction of the line elements per unit length of the pattern strip is determined by the local area brightness in the picture element pattern through which the pattern strip extends. The areas of the line elements differ by their optically effective elements from the areas of the background and / or the pixel pattern. The pixel patterns and line patterns are composed of characters, lines, tissue and frieze patterns, letters, and so on. The security element can be combined with those mentioned in the aforementioned diffractive security patterns of EP-A 0 105 099 and EP-A 0 330 738.

Embodiments of the invention are illustrated in the drawings and will be described in more detail below.

Figur 1

ein Sicherheitselement mit einem vergrösserten Ausschnitt,

Figur 2

Lettern als Bildelementmuster in Bildelementen,

Figur 3

einen Querschnitt durch das Sicherheitselement,

Figur 4

eine Mattstruktur,

Figur 5

den vergrösserten Ausschnitt bei einem Drehwinkel δ,

Figur 6

den vergrösserten Ausschnitt beim Drehwinkel δ₁,

Figur 7

den vergrösserten Ausschnitt beim Drehwinkel δ₂,

Figur 8

Kleinbilder im Sicherheitselement,

Figur 9

Detailaufbau im Bildelement und

Figur 10

Helligkeitssteuerung mit Musterstreifen.

Show it:

FIG. 1

a security element with an enlarged detail,

FIG. 2

Letters as picture element patterns in picture elements,

FIG. 3

a cross section through the security element,

FIG. 4

a matt structure,

FIG. 5

the enlarged section at a rotation angle δ,

FIG. 6

the enlarged section at the angle of rotation δ ₁ ,

FIG. 7

the enlarged section at the angle of rotation δ ₂ ,

FIG. 8

Small pictures in the security element,

FIG. 9

Detail construction in the picture element and

FIG. 10

Brightness control with pattern stripes.

In FIG. 1, 1 denotes a diffractive security element, 2 a halftone image of pattern elements, 3 a greatly enlarged detail of the security element 1, 4 picture elements, 5 background fields and 6 picture element patterns. The pattern elements of the halftone image 2 are the pixel-like picture elements 4, which are tessellated from surface parts put together. Microscopically fine surface structures in the surface parts of the picture elements 4 modify light incident on the security element 1 as a function of the direction of illumination and observation. The surface parts with the light-modifying surface structures comprise at least the background fields 5 and the pixel patterns 6. The surface structures may be equipped with a reflection layer for enhancing the light-modifying effect.

In the illustration of Figure 1, the surface of the security element 1 is aligned to a coordinate system with the coordinate axes x and y for ease of description. Further, the surfaces of the background fields 5 and the pixel pattern 6 are held in white or unpatriated white for illustrative reasons in the drawings, the background fields 5 and the pixel pattern 6, unlike in halftone prints produced without indication of the lighting and observation direction no evidence of their Allow surface brightness.

As shown in enlarged section 3 of Fig. 1, in one embodiment, the surface of the security element 1 is divided into a plurality of the picture elements 4, which are smaller than 1 mm in at least one dimension, e.g. The pixels 4 have the shape of a square, a rectangle, a polygon or are a conformal image of one of these surfaces. Boundaries between the picture elements 4 are entered only for illustrative reasons in the drawings. The surface of each picture element 4 has at least the background field 5 and the picture element pattern 6 arranged on the background field 5, wherein the picture element pattern 6 is a contiguous surface part or also consists of a group of surface parts.

The areal brightness of the halftone image 2 at the location P which corresponds to the picture element 4 having the coordinates (x _P ; y _P ) is determined, preferably taking into account the areal brightness of the locations in the halftone image 2 corresponding to the adjacent picture elements 4 and / or the gradient the area brightness of the location P, the area ratio of the pixel pattern 6 in the area of the pixel 4 having the coordinates (x _P ; y _P ). For example, the area ratio of the image element pattern 6 in the image element 4 with the coordinates (x _P, y _P) is all the greater, the greater is the area of brightness at the location P of a master image of the halftone image. 2 In order to form a halftone image 2, all pixel patterns 6 must have the same light-modifying effect under a predetermined one Have lighting and observation direction, while the background fields 5 deflect as little light in this direction of observation.

The area ratio of the pixel patterns 6 in the pixel 4 may be in the range between 0% and 100% if the shape of the pixel pattern 6 is similar to the shape of the pixel 4. By the term "similar shape" is meant shapes which are the same at the appropriate angles but of different dimensions. If the edge shape of the picture element pattern 6, which is e.g. is in the form of a star, depending on the shape of the picture element 4, the area of the surface portions of the picture element patterns 6 in the picture elements 4 is limited at the upper end, i. in the picture element 4, a portion of the background field 5 is still present. However, the pixel pattern 6 is preferably recognizable in each pixel 4, albeit in different sizes or in a narrow band in the edge shape of the pixel pattern 6 corresponding to the area fraction, in order to obtain the necessary area fraction of the pixel pattern 6 in the pixel 4. The representation of the halftone image 2 is based on a scale with predetermined levels of the surface portions of the pixel pattern 6 in the pixel 4, wherein the surface brightness of the image original is converted by means of this scale into the halftone image 2.

For example, the image original of the halftone image 2 on a base 7 has a folded band 8 and an arrow 9 which is arranged in the middle of the band 8. The area of the halftone image 2 is divided into the picture elements 4. According to the pattern elements, eg base 7, band 8, arrow 9, etc., the surface brightnesses of the image template are assigned to the picture elements 4. In the illustration of FIG. 1, the base area 7, the arrow 9 and the visible areas of the band 8 held in different grids differ from each other in their surface brightness, as in the image template. The observer recognizes on the security element 1 at least the halftone image 2 of the image original in different surface brightness gradations. Because of the relatively large pixels 4, the security element 1 is to be viewed from a minimum viewing distance of about 0.3 m or more in order to recognize the halftone image 2 well. From a reading distance of less than 30 cm, the predetermined pixel pattern 6 for the observer can still be seen by the naked eye or with a simple magnifying glass. For example, in the drawing of Fig. 1, the pixel pattern 6 is a star. In other embodiments of the security element 1, the adjacent pixel patterns 6 differ from the Reading distance <30 cm, the coarse grid of the pixel pattern 6 disturbs the recognition of the halftone image 2.

In one embodiment of the halftone image 2, the pixel patterns 6 in all pixels 4 are similar. In the example shown in FIG. 1, the star-shaped picture element pattern 6 in the picture elements 4 in areas with low surface brightness, here for the base area 7, are shown in small detail in the detail 3. The area proportions of the pixel patterns 6 are correspondingly larger in the picture elements 4, if e.g. represent the parts of the band 8 with the different from the base 7, stepped higher surface brightness. Both the surfaces of the background fields 5 and the pixel patterns 6 have, for example, general, diffractive surface structures with a reflection layer. The background fields 5 differ from the pixel patterns 6 in at least one structural parameter of the surface structure, e.g. Azimuth, spatial frequency, profile shape, tread depth, furrow curvature, etc., or in that the areas of the background fields 5 or the pixel pattern 6 are transparent, e.g. due to a local removal of the reflective layer, or covered by a colored layer (e.g., white or black). The surfaces of the Hiritergrundfelder 5 thus differ from the surfaces of the pixel pattern 6 by the light-modifying effect of their surface structures. In one embodiment of the halftone image 2, the surface structures in the areas of the background fields 5 and / or the pixel pattern 6 have additional structural parameters dependent on the coordinates (x; y).

In addition to this simple example of the halftone image 2, in particular, representations (e.g., portraits) of known personalities are suitable for the halftone images 2, and it is advantageous for the pixel patterns 6 to be related to the depicted personality, e.g. Letters of a continuous personality-written text and / or a composed melody in musical notation.

In FIG. 2, the picture elements 4 each contain a picture element pattern 6 in the form of a single letter on the background of the background field 5. The picture elements 4 are arranged in such a manner that the letters in the picture element patterns 6 have the sequence corresponding to the text. The area ratios of the letters in the field of the picture element 4 predetermined by the halftone image 2 are changed by changing the thickness and / or the font size of the letters. The thickness changes continuously or in steps within a letter if this results in a better resolution of the halftone image 2. In the drawing of Figure 2, this is shown in the letters S and E, U. The dimensions of the picture elements 4 with letters are kept correspondingly small, so that the letters can be read from close, ie viewed in the normal reading distance, but no longer from the above viewing distance. In another embodiment, the picture elements 4 are microscopically small, wherein the letters or notation can only be seen through a microscope. A text recognizable only at an at least 20-fold magnification is hereinafter called "nanotext". The illustration in FIG. 2 is a simplification and does not show the dimension of the picture elements 4 adapted to the letters, for example in the case of letters of a proportional font or the nanotext in the picture element 4 with an oblong rectangular shape with continuous, eg handwritten texts.

FIG. 3 shows a typical cross section through the security element 1. The security element 1 is a section of a layer composite 10 containing the halftone image 2 (FIG. 1). The layer composite 10 comprises at least one embossing layer 11 and a protective lacquer layer 12. Both layers 11 and 12 consist made of plastic and include a reflective layer 13 between them. In another embodiment, a scratch-resistant, tough and transparent protective layer 14 made of polycarbonate, polyethylene terephthalate, etc. also covers the entire side of the embossing layer 11 facing away from the reflective layer 13. At least the embossing layer 11 and the protective layer 14 that may be present are at least partially transparent to incident light 15 , The protective lacquer layer 12 itself or an optional adhesive layer 16 arranged on the side of the protective lacquer layer 12 facing away from the reflection layer 13 is designed to connect the security element 1 to a substrate 17. The substrate 17 is a valuable object to be authenticated with the security element 1, a document, a banknote, etc. Further embodiments of the layer composite 10 are described, for example, in the aforementioned US Pat. No. 4,856,857. In this document, the materials suitable for the construction of the laminate 10 and those for the reflective layer 13 are assembled. The reflection layer 13 is implemented as a thin layer of a metal from the group consisting of aluminum, silver, gold, chromium, copper, nickel, tellurium, etc., or is characterized by a thin layer of an inorganic dielectric, such as MgF ₂ , ZnS, ZnSe, TiO ₂ , SiO ₂ , etc., formed. The reflection layer 13 can also be several layers of different inorganic dielectrics or a combination of metallic and dielectric layers. The layer thickness of the reflection layer 13 and the choice of the material of the reflection layer 13 depend on whether the security element 1 is purely reflective, as mentioned above, only in area parts transparent, ie partially transparent, or transparent with a predetermined degree of transparency. In particular, reflective layers 13 of tellurium are suitable for individualizing the individual security element 1, since the reflective tellurium layer becomes transparent when exposed to a fine laser beam through the plastic layers of the layer composite 10 at the location of the irradiation and a window 46 is formed without the layer composite 10 being damaged. The thus introduced transparent windows 46 form, for example, an individual code. In the same way, the reflection layer 13 in the areas of the background fields 5 and the pixel pattern 6 is removed if an individual halftone image 2 is to be produced.

The reflection layer 13 in the region of the halftone image 2 has the microscopically fine surface structures diffracting the incident light 15. The surfaces of the background fields 5 are covered with a first structure 18 and in the surfaces of the pixel pattern 6, a second structure 19 is molded. For these structures 18, 19, the diffractive surface structures are used which consists of diffraction gratings, holograms, matt structures, kinoforms , Moth-eye structures and specular surfaces are selected. The reflecting surfaces comprise plane, achromatically reflecting mirror surfaces and diffraction gratings acting like a colored mirror. These color-reflecting diffraction gratings have the shape of a linear grating or cross lattice and have spatial frequencies f of more than 2300 lines / mm and reflect depending on their optically effective structure depth T selectively color components of the incident light according to the law of reflection. If the optically effective structure depth T falls below a value of about 50 nm, the incident light is reflected practically achromatically. The flat mirror surface which is parallel to the surface of the layer composite 10 should also be assigned to this group of microscopically fine surface structures as a singular relief structure, the flat, achromatically reflecting mirror surface being characterized by the spatial frequency f = ∞ or 0 and the structure depth T = 0. The Kinoforms are described in the aforementioned documents DE-OS 1957 475 and CH 653 782.

For example, one of the above-mentioned surface structures extends as a background field 5 over the entire area provided for the halftone image 2. The areas of the pixel patterns 6 are subsequently covered with the predetermined color. The inking 45 is carried out on the surfaces of the pixel patterns 6 by ink jet printing or gravure printing, e.g. Already this simplest embodiment of the security element 1 has the advantage that a copy of the security element 1 produced with a copier differs significantly from the original. In another embodiment, the paint application 45 is located in the areas of the background fields 5 or the pixel pattern 6 directly between the embossing layer 11 and the reflection layer 13. In contrast to the drawing of FIG. 3, the paint application 45 extends over the entire area of the background field 5 or Also, the windows 46 formed by the above-mentioned removal of the reflection layer 13 have the whole area of the background field 5 and the pixel pattern 6, respectively.

By way of example, the reflection layer 13 in the background fields 5 has, as the first structure 18, a reflecting surface which is embodied either as a plane mirror surface or as a diffraction grating acting as a colored mirror. In the case of illumination with daylight or with polychromatic artificial light, the incident light 15 impinges on the layer composite 10 at an angle of incidence α, the angle of incidence α between the direction of the incident light 15 and a normal 20 to the surface of the layer composite 10 being measured. Light 21 reflected by the first structure 18 leaves the composite layer 10 at a normalized angle of precipitation β, which is equal to the angle of incidence α according to the law of reflection. Only when the observer looks directly into the reflected light 21 at a narrow solid angle do the background fields 5 together make a bright impression, with the plane mirrors reflecting daylight unaltered (ie achromatic), while the diffraction gratings having a spatial frequency f greater than 2300 lines / mm reflect a typical mixed color. In the other directions of the half-space above the laminate 10, the background fields 5 are practically black.

For the first structure 18, therefore, a relief absorbing the incident light 15, which is known by the term "moth-eye structure" and whose regularly arranged, pin-shaped relief structure elements protrude from about 200 nm to 500 nm high above a base of the relief. The relief structure elements are 400 nm or less apart. The surfaces with such moth-eye structures reflect less than 2% of the incident light 15 from any direction and are black to the observer.

In the pixel patterns 6, the second structure 19 is formed, which deflects the incident light 15 substantially outside the direction of the reflected light 21. The microscopically fine reliefs of the linear diffraction gratings with a spatial frequency f in the range from 100 lines / mm to 2300 lines / mm fulfill this condition. For achromatic diffraction gratings, the spatial frequency f is selected from the range of values of f = 100 lines / mm to f = 250 lines / mm. The incident light 15 color diffraction gratings have preferred values of the spatial frequency f ranging between f = 500 lines / mm and f = 2000 lines / mm. The orientation of the grating vector k (FIG. 1) is fixed with respect to the coordinate axis x (FIG. 1) by the azimuth θ (FIG. 1). A special case of the linear diffraction gratings are those whose meandering furrows, however, such that the meandering furrows follow in the middle of a straight line. These diffraction gratings have a larger area in the azimuth at which they are visible to the observer.

On the second structure 19, the incident light 15 is diffracted and deflected as light waves 22, 23 in the minus first diffraction order and as light waves 24, 25 in the plus first diffraction order according to its wavelength from the direction of the reflected light 21, the blue-violet light waves 23 , 24 are bent away from the direction of the reflected light 21 by the minimum diffraction angle ± ε. The light waves 22, 25 with larger wavelengths are deflected by correspondingly larger diffraction angles.

The incident light 15 and the normal 20 determine an observation plane which, in the representation of FIG. 3, coincides with the plane of the drawing and is parallel to the coordinate axis y. The viewing direction of the observer lies in the observation plane and the eye of the observer receives the reflected light 21 of the specular background fields 5 when the viewing direction and the normal 20 include the angle of reflection β.

The diffraction gratings function optimally if their grating vector k is aligned parallel to the observation plane, which in this case is identical to the diffraction plane. In this case, the diffracted light beams 21 to 24 are in the observation plane and generate, according to the viewing direction, a predetermined color impression in the eye of the observer. If the grating vector k is not in the observation plane, ie, not within an observation angle of about ± 10 ° to the observation plane, or the light rays 21 to 24 are not in the viewing direction, the observer occupies the surface of the diffraction grating or the pixel pattern 6 because of the few , at the second structure 19 scattered light as a dark gray area true. With a skilful choice of the structural parameters in relation to the content of the halftone image 2, therefore, one of the diffraction gratings can also be used as the first structures 18 of the background fields 5. On the other hand, an overlay of the diffraction grating with one of the matt structures described below causes an enlargement of the viewing angle of the picture element pattern 6.

In the drawing of Figure 3, the profile of the second structure 19 is exemplified with a symmetrical sawtooth profile of a periodic grating. For the structures 18, 19 in particular also one of the other known profiles, such as. asymmetrical sawtooth profiles, rectangular profiles, sinusoidal and sinusoidal profiles, etc., which form a periodic lattice with straight, meandering or otherwise curved or circular furrows. Since the material of the embossing layer 11 with a refractive index n of approximately 1.5 fills the structures 18, 19, the optically active structure depth T is n times the shaped geometric structure depth. The optically effective structure depth T of the periodic gratings used for the structures 18, 19 is in the range of 80 nm to 10 μm, wherein for technical reasons the relief structure having a large structure depth T has a low value of the spatial frequency f.

If the second structure 19 of the pixel pattern 6 must deflect the incident light 15 into a large solid angle region of the half space above the layer composite 10, a matt structure, eg a kinoform, an isotropic or an anisotropic matt structure, is advantageously suitable. The pixel patterns 6 are from all viewing directions visible as a bright surface within the solid angle determined by the matt structure. The relief structure elements of these microscopically fine reliefs are not regularly arranged as in the diffraction grating. The description of the matt structure is made with statistical parameters, such as average roughness R _a , correlation length I _c , etc. The microscopically fine relief structure elements of the matt structures suitable for security element 1 have values for the average roughness value R _a ranging from 20 nm to 2,500 nm. Preferred values are between 50 nm and 1000 nm. In at least one direction, the correlation length I _{c has} values in the range of 200 nm to 50,000 nm, preferably between 1,000 nm and 10,000 nm. The matt structure is isotropic when microscopic fine relief features have no azimuthal preferred direction, which is why the scattered light with an intensity that is greater than a predetermined threshold, for example, by the visual detectability is uniformly distributed in a predetermined by the scattering power of the matte structure solid angle in all azimuthal directions. The solid angle is a cone whose tip is on the illuminated by the incident light 15 part of the laminate 10 and whose axis coincides with the direction of the reflected light 21. Highly scattered matt structures distribute the scattered light into a larger solid angle than a weakly scattering matt structure. If, on the other hand, the microscopically fine relief structure elements have a preferred direction in the azimuth, an anisotropic matt structure is present which anisotropically scatters the incident light 15, the solid angle predetermined by the scattering power of the anisotropic matt structure having an elliptical cross-section as its cross-section, whose major axis is perpendicular to the preferred direction the relief structure elements is aligned. In contrast to the non-achromatic diffraction gratings, the matt structures scatter the incident light 15 achromatically, ie independently of its wavelength, so that the color of the scattered light essentially corresponds to that of the light 15 incident on the matt structures. For the observer, the area of the matt structure has a large surface brightness in daylight and, like a sheet of white paper, is visible practically independent of the azimuthal orientation of the matt structure.

FIG. 4 shows an exemplary cross section through one of the matt structures, which is enclosed as a second structure 19 between the embossing layer 11 and the protective lacquer layer 12. According to the structure depth T (FIG. 3) of the diffraction gratings, the profile of the matt structure has the average roughness value R _a , but the greatest differences in height H occur between the microscopically fine relief structure elements of the matt structure up to approximately 10 times the average roughness value R _a . The height differences H of the matt structure, which are important for the molding, thus correspond to the structure depth T in the case of the periodic diffraction gratings. The values of the height differences H of the matt structures are in the above-mentioned range of the structure depth T.

A special design of the matt structure is superimposed with a "weakly acting diffraction grating". The weakly acting diffraction grating has a low diffraction efficiency because of the low structure depth T between 60 nm and 70 nm. A spatial frequency in the range of f = 800 lines / mm to 1000 nm lines / mm is preferred for this application.

Circular diffraction gratings with a period of 0.5 μm to 3 μm and with spiral or circular grooves can also be used for the pixel pattern 6. The diffractive structures which increase the viewing angle are summarized below under the term "diffractive scatterers". The term "diffractive spreader" is thus to be understood as meaning a structure from the group of isotropic and anisotropic matt structures, kinoforms, the diffraction grating with circular grooves at a furrow spacing of 0.5 μm to 3 μm and the matt structures superimposed with a weakly acting diffraction grating

Returning to Figure 3: In a first embodiment, the halftone image 2 (Figure 1) is static, that is, in a wide range of spatial orientation under a common viewing condition at said viewing distance and when illuminated with white incident light 15, the halftone image 2 does not change , Only upon closer inspection does the observer notice that the halftone image is divided into the picture elements 4 (Figure 1) and the picture element patterns 6 have predetermined shapes. The first structure 18 in the background field 5 reflects or absorbs the incident light 15. The second structure 19 of the pixel patterns 6 is one of the diffractive scatterers. The second structure 19 scatters or diffracts the incident light 15 such that the pixel pattern 6 is visible in a large solid angle predetermined by the diffractive spreader. When the security element 1 is illuminated with white light 15, the observer sees the halftone image 2 arranged in said viewing distance in a gray scale, since the observer sees the image elements 4 with a large surface portion of the pixel pattern 6 in a large surface brightness and the image elements 4 with a smaller area fraction of the pixel pattern 6 perceives in a lower surface brightness. The visibility of the halftone image 2 behaves much like a halftone image printed on paper in black and white. However, the halftone image 2 is poor or not recognizable, or contrast reversal of the halftone image may occur if the viewing direction is outside the solid angle of the scattered or diffracted light. If the first structures 18 a If the security element 1 is oriented exactly in such a way that the halftone image 2 is viewed exactly opposite to the direction of the reflected light 21, the contrast also reverses. The bright picture elements 4 before the tilting of the security element 1 are now darker than the previously dark picture elements 4, which are now much brighter in the reflected light 21, and vice versa. The tilting of the security element 1 takes place about an axis perpendicular to the observation plane and parallel to the plane of the security element. 1

For the representation of the halftone image 2, the combinations of the first and second structures 18, 19 compiled in Table 1 are preferred.

In a second embodiment, the structures 18, 19 are selected such that the contrast in the halftone image 2 changes when the security element 1 is rotated or tilted about an axis parallel to the normal 20 by a rotation angle in its plane. The contrast envelope is therefore easier to observe compared to the first embodiment of the security element 1. The first structure 18 in the background fields 5 is e.g. a linear diffraction grating whose grating vector k is the azimuth θ = 0 ° (Figure 1), i. in the direction of the coordinate axis x. The pixel patterns 6 are occupied by one of the diffractive scatterers. The observer rotates the security element 1 around the normal 20 and sees the halftone image 2 arranged in the viewing distance of 50 cm or more in the gray scale, except when the grating vector k of the first structure 18 is aligned substantially parallel to the observation plane and the viewing direction of the observer in the direction one of the light beams 21 to 25 is directed. When tilting the thus aligned security element 1 about an axis parallel to the coordinate axis x the halftone image 2 in contrast reversal changes its color corresponding to the deflected in the eye of the observer diffracted light beam 22 to 25. In the angular ranges, not from the diffracted light beams 22 to 25 a Be taken diffraction order, the halftone image 2 is again recognizable in the gray scale.

In a third embodiment of the security element 1, both fields, the background fields 5 and the pixel patterns 6, the structures 18, 19 of the diffraction gratings splitting the incident light 15 into colors which differ only in the azimuth θ of the grating vectors k. The grating vector k is aligned for the diffraction gratings of the pixel pattern 6 parallel to the coordinate axis y, ie with the azimuth θ = 90 ° or 270 °. The grating vector k for the diffraction gratings of the background fields 5 differs in azimuth from the grating vectors k in the pixel patterns 6 and has, for example, the azimuth θ = 0 ° or 180 °. The observer with the viewing direction parallel to the diffraction plane, which contains the coordinate axis y and the grating vector k of the first structures 18, sees in the above viewing distance the halftone image 2 in one of the diffraction colors in the contrast of the image original, ie he sees the luminous surfaces of the pixel patterns 6 With the second structures 19 brighter than the scattered light of the background fields 5. During the rotation of the composite layer 10 in its plane, the contrast disappears in the halftone image 2 to form again at the rotation angle α of 90 ° or 270 °, since the lattice vectors k first structure 18 are aligned in the background fields 5 parallel to the observation plane and therefore the background fields 5 now light up. The halftone image 2 is visible to the observer in inverted contrast and in the same color. If, in addition, the spatial frequencies f of the first and second structures 18, 19 differ, for example, by 15 to 25%, not only the contrast but also the color in the halftone image 2 changes during rotation. At viewing angles outside the diffracted light beams 22, 23 and 24, 25 the diffraction orders, the halftone image 2 is not recognizable for lack of contrast.

If the spatial frequencies f of the first and / or the second structures 18, 19 are selected in a location-dependent manner, the halftone image 2 shows a colored image which, for example, corresponds to the colors of the image template at a predetermined tilt angle.

In a modified second and third embodiment of FIG. 1, the first structures 18 (FIG. 3) of the background fields 5 have different directions of the grating vectors k, ie have azimuths θ in the range of -80 ° ≦ θ ≦ 80 °, so that the rotation of the composite layer 10 in this azimuth region in the dark contrastless image of the security element 1, the surfaces of those structures 18 light up in color whose grid vector k are just parallel to the observation plane.

In another preferred embodiment of FIG. 1, the linear diffraction gratings are shaped in the background fields 5 in such a way that the diffraction gratings with parallel grating vectors k are arranged in rows of the picture elements 4. However, the azimuths θ of the lattice vectors k of one row differ from the azimuths θ of the lattice vectors k of the background fields 5 in the two adjacent rows of the lattice vectors k Picture elements 4. For example, three rows A, B, C are arranged with predetermined azimuth values. No grid vectors k of the background fields 5 are aligned parallel to the coordinate axis y, as in the case of the grid vectors k of the pixel patterns 6. The observer therefore sees the halftone image 2 in the correct contrast when the coordinate axis y of the halftone image 2 is in the observation plane. The pixel patterns 6 are bright and the background fields 5 are dark. When rotated about the normal 20 (Figure 3), the security element 1 changes its appearance when the laminate 10 (Figure 3) is viewed under the same lighting and observation conditions as in Figure 1. The halftone image 2 becomes the dark contrastless image, wherein in the rows A, B, C, the background areas 5 light up in color whose grid vector k is just parallel to the observation plane.

FIG. 5 shows the detail 3 from FIG. 1 after a rotation about the angle of rotation δ. In the aforesaid viewing distance, the halftone image 2 (Fig. 1) appears as a dark, contrasting surface on which are arranged brightly illuminated stripes formed by the A rows 26 of the picture elements 4 (Fig. 1) with the background fields 5 Grid vectors k (Fig. 1) are aligned at the rotation angle δ parallel to the track 27 of the observation plane at the level of the layer composite 10.

FIG. 6 shows that at the angle of rotation δ _1, however, the background fields 5 of B rows 28 light up as soon as the grid vectors k (FIG. 1) of the background fields 5 in the B rows 28 are aligned parallel to the track 27. The background fields 5 of the A rows 26 now form part of the non-contrast dark area of the security element 1 (FIG. 1), since the grid vectors k of the A rows 26 are rotated out of the observation plane. For the same reason, in FIG. 7, the background fields 5 of C rows 29 are bright at the angle of rotation δ ₂ and those of the other rows 26, 28 are dark. In other words, the rows 26, 28, 29 in the order ABC ..., ABC ... etc. arranged cyclically repetitively on the security element 1 (Fig. 1), wander bright when the security element 1, from the Spatialfrequenz f of the first structures 18 (FIG. 3) used in the background fields 5, colored stripes over the surface of the security element 1 (FIG. 1), until the rotation angle δ = 180 ° or 0 ° the halftone image 2 without colored stripes again visible since the coordinate axis y and the grating vectors k (FIG second structures 19 (FIG. 3) in the pixel patterns 6 are aligned parallel to the track 27.

If the second structure 19 is one of the diffractive scatterers, the halftone image 2 is visible substantially independently of the angle of rotation δ, whereby the colored stripes of the rows 26, 28, 29 appear to wander over the halftone image 2 when the security element 1 is rotated.

Below the reading distance, the rows 26, 28, 29 of the picture elements 4 are resolved and the background fields 5 and the picture element patterns 6 (Figure 1) are resolved under the same conditions as above.

In FIG. 8, the halftone pattern 2 has a flag-like division, in which a band 8 bordered by borderlines 30 is arranged on the base surface 7. The picture elements 4 visible in the enlarged section 3 have a greater areal proportion of the picture element patterns 6 for the band 8 than for the base area 7. The areas of the pixel patterns 6 are covered with one of the diffractive scatterers and the areas of the background fields 5 with one of the diffraction structures. The background fields 5, the first. Structures 18 (FIG. 3) have the same spatial frequency f.sub.s, the grating vectors k (FIG. 1) which are aligned parallel to one another, ie have the same azimuth .theta..sub.90 or 270.degree. (FIG. 1), are not in simple straight strips 26 (FIG. 7), 28 (FIG. 7), 29 (FIG. 7) of the picture elements 4, but in such a way that the picture elements 4 with these background fields 5 form at least one small picture 31 visible at a predetermined viewing angle. In the drawing of FIG. 8, for example, the small images 31 to 35 represent circular ring segments. The small images 31 to 35 are represented by the values of the spatial frequency f and the azimuth θ (FIG. 1) of the grating vectors k (FIG. 1) used for the first structures 18 of the background fields 5. Fig. 1). The background fields 5 that are not used for the small images 31 to 35 have, for example, a reflective surface or a moth eye structure. In the mentioned viewing distance, the observer sees the halftone image 2 in shades of gray independently of the angle of rotation δ (FIG. 5). On the surface of the security element 1 (FIG. 1), the observer recognizes those small images 31, 32, 33, 34, 35 whose lattice vectors coincidentally lie in the observation plane when the security element 1 is rotated, the color of the visible small images 31 to 35 being determined by the Spatialfrequenz f and by the tilt angle of the security element 1 is determined. For example, when the security element 1 is rotated around the normal 20 (Figure 3) in a predetermined order, one or more of the small images 31-35 illuminate and produce a kinematic impression, ie when rotated about the normal 20 (Figure 3) the locations travel When tilting about the coordinate axis x, the color of the currently visible small images 31 to 35 change. In one embodiment, a plurality of these small images 31 to 35 are arranged so that some, here provided with the reference numeral 31 and 32, from them at a determined by the rotation angle δ and the tilt angle orientation of the security element 1 form a predetermined sign, ie the small images 31 to 35 are used advantageously to establish a predetermined orientation of the security element 1 in space.

The small images 31 to 35 are not limited to simple characters only, but in one embodiment are pixelized images, such as images. a greatly reduced image of the halftone image 2 or a graphical representation of line and / or surface elements.

In another embodiment of the halftone image 2, the background fields 5, e.g. of the small picture 31, the reflecting cross grating with the spatial frequency f ≥ 2300 lines / mm as the first structure 18. The small image 31 is only visible to the observer if he looks directly into the reflected light 21 (FIG. 3) and recognizes the small image 31 in the mixed color characteristic of these high-frequency diffraction gratings, or if, in view of the large diffraction angles ε (FIG. 3) viewed the small image 31 at the corresponding tilt angle and the small image 31 in bright, blue-green color on the dark field of the security element 1 sees.

In another embodiment, the background fields 5 have a diffraction grating with the azimuth θ = 0 °, which separates the incident light 15 (FIG. 3) into colors. In the pixel pattern 6, a diffractive spreader is molded. The halftone image 2 is visible at the angles of rotation δ = 90 ° and 270 ° in brightness levels of a color with inverted contrast and outside these angles of rotation in grayscale in the contrast of the original image.

In a further embodiment, the background fields 5 as the first structure 18, the asymmetric diffraction grating with the azimuth θ = 0 °, whose grooves are aligned parallel to the coordinate axis y. The pixel patterns 6 are occupied by the same asymmetrical diffraction grating, however, the grating vector k is the second structure 19 (FIG. 3) oriented opposite to the grating vector k of the first structure 18, ie the value of the azimuth θ = 180 °. The halftone image 2 is visible only at the angles of rotation δ = 0 ° and 180 ° in a color dependent on the spatial frequency f and the observation condition and in achromatic asymmetric diffraction gratings in the color of the incident light 15 (FIG. 3) Rotation of 180 °, the contrast of the halftone image 2 respectively reversed. Outside these two angles of rotation, the contrast disappears in halftone image 2.

Table 2 lists the combinations of diffractive structures for the background fields 5 and the pixel patterns 6 in which a contrast inversion or contrast loss with color effects occurs at predetermined rotational angle values δ.

FIG. 9 shows a further embodiment of the picture elements 4. The picture element pattern 6 is band-shaped and has the outline of a pattern, here in the form of a star. The background field 5 splits into at least two surface parts when the band-shaped picture element pattern 6 is self-contained. The width of the pixel pattern 6 determines the area fraction of the pixel pattern 6 in the pixel 4. So that the halftone image 2 (FIG. 8) does not exhibit any unwanted modulation of the brightness due to a too regular arrangement of the pixels 4 or the background fields 5, the pixel patterns 6 of FIGS adjacent picture elements 4 eg by their orientation with respect to the coordinate system x, y. In the observation distance, the observer sees the halftone image 2, which dissolves into the pixel pattern 6 arranged in the picture elements 4 only in the reading distance.

In a further embodiment of the security element 1, as shown in the enlarged detail 3 of FIG. 9, 2 pattern strips 36 are arranged in the area of the halftone image, which extend at least over part of the area of the halftone image 2. The pattern strips 36 have a width B in the range 15 microns to 300 microns. For the sake of simplicity, the pattern strips 36 are drawn parallel to one another in FIG. 9 and contain a line pattern consisting of a surface strip 40 (FIG. 10), for example a Greek frieze, as can be seen in the section 3. In another embodiment, the line pattern in the pattern strip 36 is formed as a nanotext whose letters have a letter height which is less than the width B of the pattern strips 36. Other designs of the line pattern include simple straight or meandering lines, sequences of pictograms, etc. Also forming an array of simple, straight or curved line elements the line pattern alone or in combination with the frieze and / or the nano-text and / or the pictograms. The areas of the line patterns are covered with a diffractive pattern structure 37 and have a line width of 5 μm to 50 μm. The line pattern only partially covers the background fields 5 and / or the pixel patterns 6 within the area of the pattern strip 36, so that the halftone image 2 (FIG. 1) generated by the first and second structures 18 (FIG. 3), 19 (FIG. not noticeably disturbed. The pattern structure 37 differs from both the first and the second structures 18, 19 in at least one structural parameter. For the pattern structures 37, the diffraction gratings which split the incident light 15 (FIG. 3) into colors with the spatial frequencies f of 800 lines / mm to 2000 lines / mm are preferably suitable. If the first and / or the second structures 18, 19 are not covered with a diffractive spreader, the diffractive spreader is also suitable for the pattern structure 37. In one embodiment of the pattern strips 36, at least the structural parameters spatial frequency f and / or the azimuthal orientation of the grating vector of the pattern structures 37 are selected location-dependent, ie the said structure parameters are functions of the coordinates (x, y).

FIG. 10 shows the picture element 4 with the pattern strips 36 in detail. The pattern strips 36 extend over the background field 5 and the picture element pattern 6. For example, the picture element pattern 6 has, for the sake of simplicity, the illustrated U-shape with the legs 38, 39 connected to a connecting piece. With the aid of the area fraction of the line pattern in the pattern strip 36, the area brightness within the picture element pattern 6 is controlled. The areal brightness changes within the pixel pattern 6, as shown in the drawing of FIG. 10, by widening areal strips 40 of the line pattern in the pattern strip 36. The areal brightness of the pixel pattern 6 in the left leg 38 is broadened as compared to that of the connector the surface strip 40 is reduced. For an increase in the brightness of the pixel pattern 6 with respect to that of the connector, for example in the right leg 39, the width of the surface strips 40 is reduced. Since the diffraction grating, in order to be effective, must include at least 3 to 5 grooves in the surface strip 40, the line width of the surface strips 40 must not be less than a minimum value depending on the spatial frequency f and the direction of the grating vector k (FIG. 1). A further increase in the brightness of the pixel pattern 6 causes a resolution of the surface strips 40 in small spots 41, so that the larger area for increased brightness of the pixel pattern 6 contributes. The same applies to the modulation of the background fields 5, for example in a line region 42.

In the embodiment of the picture elements 4 according to FIG. 9, for example, the line width of the surface strips 40 in the background fields 5 is the same on the whole area of the halftone picture 2, while the area brightness of the picture element patterns 6 corresponding to the picture template for the halftone picture 2 by means of the line width of the area strips 40 in FIG the pattern strip 36 is controlled. Because the small dimensions of the surface strips 40 (Figure 10) and the patch 41 (Figure 10) are not obscured by the observer's eye, e.g. Magnifying glass, microscope, etc., the area brightness of the pixel pattern 6 is proportional to the remaining area with the second structure 19 (Figure 3).

If the pattern strips 36 contain the letters of a nanotext, the control of the surface brightness, as described with reference to FIG. 2, can be achieved, for example, by enlarging and reducing the thickness of the letters or by increasing the letter spacing.

Regardless of the embodiment in FIG. 10, the eye of the observer recognizes the pattern strips 36 as simple, bright lines even at a normal reading distance of less than 30 cm and under suitable observation conditions, since the pattern in the pattern strip 36 is first detected with the aid of the magnifying glass or of the microscope is to be resolved. When tilted and / or rotated, the pattern strips 36 for the observer change their color and / or light up or go out again. Given a suitable choice of the structural parameters for the pattern structures 37 (FIG. 9), the halftone image 2 (FIG. 1) illuminated by daylight and arranged at the mentioned viewing distance has colored bands 43 produced when tilting or rotating a plurality of the pattern strips 36 (FIG ) in the colors of the rainbow, which change in color and / or seem to move over the surface of the security element 1.

In one embodiment, the halftone image 2 is part of a mosaic of surface elements 44 which are covered with diffraction gratings independent of the halftone image 2 and which exhibit an optical effect according to the above-mentioned EP-A 0 105 099. In particular, in one embodiment, the pattern strips 36 are portions of the mosaic of surface elements 44 that extend across the halftone image 2.

In Table 3, preferred combinations of the structures 18 (Fig. 3), 19 (Fig. 3), 37 for the background fields 5, the pixel patterns 6 and the pattern strips 36 are assembled.

The features of the various embodiments described herein can be combined. In particular, in the description, the terms "background fields 5" and "picture element pattern 6" or "first structure 18" and "second structure 19" are interchangeable.

tables: Table 1: First structure 18 for the background field 5 Second structure 19 for the pixel pattern 6 1.1 Flat mirror or cross lattice with spatial frequencies f> 2300 lines / mm or moth eye structure Diffractive spreader 1.2 Moth-eye structure Isotropic matt texture 1.3 Moth-eye structure asymmetric achromatic diffraction grating 1.4 Superimposed diffraction gratings Anisotropic matt texture First structure 18 for the background field 5 Second structure 19 for the pixel pattern 6 2.1 Linear diffraction grating with azimuth θ = 0 ° Diffractive spreader 2.2 Linear diffraction grating with θ = 0 ° and the first spatial frequency f ₁ Linear diffraction grating with θ = 0 ° and the second spatial frequency f ₂ 2.3 Linear or meandering diffraction grating with azimuth θ ₁ ° and the first spatial frequency f ₁ , Linear or meandering diffraction grating with azimuth θ ₂ ° and the second spatial frequency f ₂ 2.4 Linear or meandering diffraction grating with azimuth θ ₁ ° = 90 ° and the first spatial frequency f ₁ Linear or meandering diffraction grating with azimuth θ ₁ ° = 0 ° and the first spatial frequency f ₁ or anisotropic matt structure 2.5 Asymmetrical diffraction grating with the azimuth θ ₁ ° = 180 ° Asymmetrical diffraction grating with the azimuth θ ₂ ° = 0 ° First structure 18 for the background field 5 Second structure 19 for the pixel pattern 6 Pattern structure 37 for the pattern strip 36 3.1 Mirror or grating with spatial frequency f of more than 2300 lines / mm Diffractive spreader Linear diffraction grating with location-dependent azimuth θ 3.2 Linear diffraction grating with location-dependent functions for azimuth and spatial frequency f ₁ Linear diffraction grating with azimuth θ = 0 ° and spatial frequency f ₂ Diffractive spreader 3.3 Linear or meandering diffraction grating with location-dependent azimuth and the first spatial frequency f ₁ Linear or meandering diffraction grating with azimuth θ ° and the second spatial frequency f ₂ Diffractive spreader 3.4 Linear or meandering diffraction grating or anisotropic matt structure with azimuth θ ₁ ° = 0 ° Linear or meandering diffraction grating or anisotropic matt structure with azimuth θ ₁ ° ≠ 0 ° Linear diffraction grating with spatially dependent spatial frequency

Claims (17)

1. Diffractive security element (1) having a half-tone image (2), comprising area parts which are covered by microscopically fine surface structures (18; 19; 37) and are enclosed in a layer composite (10) comprising at least one transparent embossed layer (11), a protective lacquer layer (12) and a reflective layer (13), which comprises the surface structures (18; 19; 37) and is embedded between the embossed layer (11) and the protective lacquer layer (12), wherein the area parts, together with the first surface structures (18), form background fields (5) and the area parts, together with the surface structure (19), which differs from the first surface structures (18) in at least one structure parameter, form image-element patterns (6) and the area of the half-tone image (2) is divided into a multiplicity of image elements (4), which are composed of the area parts of the image-element pattern (6) and the background field (5) and are smaller than 1 mm at least in one dimension,
   characterized in that
   the image-element patterns (6) in the image elements (4) are of the same size, in that pattern strips (36) having a line pattern of a width (B) of 15 µm to 300 µm extend at least over part of the area of the half-tone image (2) and partially cover the background fields (5) and image-element patterns (6), in that the line pattern is made up of area strips (40) having pattern structures (37) and having line widths in the range from 5 µm to 50 µm, wherein the line patterns comprise letters, texts, line elements and pictograms and the pattern structures (37) differ from the first and second surface structures (18; 19) in at least one structure parameter [13], in that the line width of the area strips (40) in the background fields (5) is constant and in that the area brightness of the image elements (4) is controlled, by means of the line width of the area strips (40) on the image-element pattern (6), such that the area proportion of the image-element pattern (6) which is not covered by the line pattern is determined according to the area brightness of the image original of the half-tone image (2) at the location of the image element (4) and taking into account the area brightness of the neighbouring image elements (4).
2. Diffractive security element (1) according to Claim 1, characterized in that the first and the second surface structures (18; 19) are linear diffraction gratings having spatial frequencies in the range from 150 lines/mm to 2000 lines/mm.
3. Diffractive security element (1) according to Claim 1 or 2, characterized in that the surface structures (18; 19) are linear diffraction gratings having grating vectors (k), in that the grating vectors (k) of the second surface structures (19) are parallel in the image-element patterns (6) and in that the grating vector (k) of the image-element patterns (6) differs in the azimuth (θ) from the grating vectors (k) of the first surface structures (18) in the background fields (5).
4. Diffractive security element (1) according to Claim 3, characterized in that the image elements (4), whose first surface structures (18) in the background fields (5) have the same azimuth (θ) as the grating vectors (k), are arranged in rows (26; 28; 29) on the half-tone image (2) according to their azimuth (θ) of the grating vector (k).
5. Diffractive security element (1) according to Claim 4, characterized in that the neighbouring rows (26; 28; 29), which differ in the azimuth (θ) of the grating vectors (k), are arranged on its surface in the sequence ABC, ABC in a cyclically repetitive manner.
6. Diffractive security element (1) according to Claim 1, characterized in that the first surface structures (18) and the second surface structures (19) are meandering diffraction gratings whose spatial frequencies are chosen from the range from 150 lines/mm to 2000 lines/mm and in that the meandering diffraction gratings of the background fields (5) and of the image-element patterns (6) differ at least in the azimuth range (θ) of the grating vectors (k).
7. Diffractive security element (1) according to Claim 1 or 2, characterized in that the first surface structures (18) and the second surface structures (19) are asymmetrical diffraction gratings, wherein the grating vectors (k) of the asymmetrical diffraction gratings of the first surface structures (18) are oriented opposite to the grating vectors (k) of the second surface structures (19).
8. Diffractive security element (1) according to Claim 1, characterized in that a diffractor from the group of the isotropic and anisotropic matt structures, kinoforms, diffraction gratings having circular trenches with a trench spacing from 1 to 3 µm and the matt structures superimposed by a diffraction grating is selected as the second surface structure (19) in the areas of the image-element patterns (6).
9. Diffractive security element (1) according to Claim 8, characterized in that the background fields (5) have a structure from the group comprising planar mirrors, cross-gratings having spatial frequencies of more than 2300 lines/mm and moth-eye structures as first surface structure (18).
10. Diffractive security element (1) according to Claim 8, characterized in that the background fields (5) have a linear diffraction grating having a spatial frequency in the range from 150 lines/mm to 2000 lines/mm and having grating vectors (k) oriented parallel to one another as first surface structure (18).
11. Diffractive security element (1) according to Claim 1 or 2, characterized in that the first surface structures (18) and the second surface structure (19) are linear or meandering diffraction gratings differing in the spatial frequency (f).
12. Diffractive security element (1) according to one of Claims 1 to 11, characterized in that the spatial frequency (f) of the linear diffraction gratings in the pattern structures (37) is selected from the range from 800 lines/mm to 2000 lines/mm.
13. Diffractive security element (1) according to Claim 12, characterized in that the spatial frequency (f) of the linear diffraction gratings in the pattern structures (37) depends on the location on the half-tone image (2).
14. Diffractive security element (1) according to Claim 12 or 13, characterized in that the azimuthal orientation of the grating vector of the linear diffraction gratings in the pattern structures (37) depends on the location on the half-tone image (2).
15. Diffractive security element (1) according to one of Claims 1 to 7, characterized in that the pattern structure (37) is one of the diffractors.
16. Diffractive security element (1) according to Claim 1, characterized in that the half-tone image (2) is part of a mosaic of area parts (44) covered by surface structures which are independent of the half-tone image (2).
17. Diffractive security element (1) according to Claim 1, characterized in that the layer composite (10) is designed for adhesively bonding to a substrate (17).

Images