DE19809503A1 - Device for the production of individual holograms for securing documents - Google Patents

Description

The invention relates to a master hologram for copying a hologram in the Contact procedure. The invention further relates to a device for producing a individual hologram, in particular a contact copy of a hologram with a radiation source with laser radiation for irradiating a master and one Films. Finally, the invention relates to a hologram, in particular a copy of an egg contact hologram. The individual holograms can be used to secure Documents.

When producing holograms, a master hologram and a holo graphic film irradiated with laser radiation. In the series production of Holo The holograms are preferably produced by contact copying. In In this case, the master and the film are in contact with each other.

A hologram is created on the holographic film with that on the master available information. With a master can therefore in series production holograms are easily produced, all of the same information include. However, if the holograms are completely or partially different, individual duel information should result in the series production Schwie difficulties. A separate master must then be created for each hologram. This is complex and expensive.

The object of the invention is to provide a master for copying a hologram especially to suggest by contact copy with the holograms that differ contain information that can be easily produced.

According to the invention, this object is achieved in that the master consists of a plurality of preferably three, individual masters, each with different information wear one.

Advantageous further developments are described in the subclaims.

The first master hologram is preferably the hologram of a focusing screen.

Another advantageous development is characterized in that from the or the master holograms of illumination holograms. The Illumination holograms are used to shape the coherent radiation. The Illumination hologram is designed such that it is the coherent beam primarily in predetermined areas on the master and the film which holograms or hologram components are to be generated. Hereby the efficiency or the radiation yield is significantly improved.

The illumination hologram can be a computer generated hologram (CGH) getting produced. However, it can also be produced interferometrically.

According to a further advantageous development, a color device is available for colored irradiation of the master and the film. This makes it, for example possible, the individual hologram, i.e. that part of the hologram, that carries individual information in color. Preferably one color-capable LCD used. This can be irradiated with white light lasers or but with three different colored lasers in the usual color triangle.  

According to a further advantageous development, there is a device for imprinting different aspect angle available. It can be both plain and multi-colored holograms with different aspect angles are imprinted. This makes it possible to generate a stereogram or a multi-stereogram, without additional aids such as polarized glasses as spatial Representation can be recognized, namely stereoscopically or (with Multistereo gram) also autostereoscopically.

The focusing screen master is preferably provided with a reflection hologram provides, this reflection hologram in turn from a transmission Hologram of a ground glass screen is made. So the ground glass becomes one Transmission hologram produced, from which the ground glass master with a reflection hologram is made. It is a ground glass in the form of a lenticular grid. A scattering effect is achieved through the lenticular grid. Well defined waves result from certain points. An orderly or structured adhesive disc is used. Because a struktu certain pattern can be specified and found that to adjust.

The ground glass master can be in at least two wavelengths, preferably in three wavelengths. Because at least two wavelengths color effects can be created. The use is advantageous of three wavelengths.

The second master preferably contains constant information. Here can be an identifier (also known as a "logo") preferably a three-dimensional identifier or three-dimensional logo.  

A master hologram that contains a three-dimensional logo can be used after a usual methods are recorded as a transmission hologram. To do this three-dimensional object, i.e. a three-dimensional pattern of the logo recorded in a reflection hologram using a conventional method. This holo grams can then be copied in a second step, namely by that the first hologram produced initially is illuminated with coherent light and in the image plane a second hologram - preferably as a reflection Hologram - is generated. This second hologram is then the master hologram with the three-dimensional logo, for example for a contact copy process can be used to produce holograms.

It is also advantageous if the third master be a machine-readable feature contains. If the above-mentioned second master, who has a constant Informati on contains, does not exist, the master provides with the machine-readable Feature of course represents the second master.

The individual master holograms are preferably combined into a single overall master exposed. This master, which contains the information of all individual masters, is then used to make holograms. The exposure of the three Master or master holograms in a single master hologram or one umpte master is preferably carried out sequentially. That way he did generated master hologram contains the image information of the preferably three Aus gang holograms and is the master hologram (overall master hologram) for the subsequent series production. Preferably the three masters become two or three different wavelengths are recorded.

In the case of a device for producing an individual hologram, in particular a contact copy of a hologram with a radiation source for laser radiation, especially laser radiation, for irradiating a master and a film the above-mentioned task solved by a modulation device, in particular  another an LCD, for modulating the coherent radiation. Preferably be the master and the film are irradiated with an amplitude-modulated reference beam. The coherent radiation or laser radiation or the amplitude-modulated ref renzstrahl contains the image information to be applied to the film and which is to be embodied in the hologram produced. When copying also uses two or three different wavelengths of lighting adapted to the masters and their manufacturing processes.

The modulation is preferably implemented by an LCD (Liquid Crystal Display). The LCD or the other modulation device can in turn provide the image information by a computer generating process or a scanner process or a receive other method, for example as a video signal.

The entire surface of the coherent radiation can be applied to the master and the film be brought, so by radiation that the entire image area at once thins out. However, the coherent radiation is preferably obtained by a scanner, ie Applied to the image area in a scanner process. The scanner is used for scanning the coherent radiation over the master and the film. The scan nerstrahl is modulated while scanning the image area, at for example with the gray level applicable to the respective pixel. As with happen on a television picture, i.e. in rows and columns. They are also mixed shapes possible, in which an entire line is simultaneously on the image area is thrown and then this line in a direction perpendicular to it over the image area is scanned. Such a line scan is preferably used.

There are advantages to using a scanner method. For the exposure of the area detected in each case can be a higher energy per when scanning Area element can be used, the respective exposure time of this area ches reduced. The total exposure time then remains approximately the same. There however, the area covered only for a shorter or significantly shorter time  is exposed, the picture is much less sensitive to movement. Move conditions of the film in relation to the master can be compensated are generated, especially when contact copying in the photographic material of the film after clamping and lamination. Due to the higher light energy, which is used in the scanner process, and the achievable thereby The shortening of the exposure time can cause movements, especially in the photo material of the film, which are tolerated with a total illumination of the image would lead to a significant deterioration in quality. Furthermore, it is possible when using a scanner method, already after a substantial Lich shorter time after the film is clamped with the exposure process begin, which significantly shortens the cycle time in series production.

It is particularly advantageous to perform line-by-line scanning. This can the LCD, from which the image information comes, is also scanned line by line. This information can then be given directly to the laser or the laser line and are used for the illumination.

Finally, the invention relates to a hologram, in particular a contact copy a hologram, which according to the invention with a master according to the invention and / or is produced with a device according to the invention.

It is advantageous if the hologram has a color shift (color shift). For this purpose, the holograms produced or copied by the master can be processed according to Exposure and fixation experience a color shift. Above all, this can generated by the fixation. The color shift causes that did not constrict the hologram with a laser of the same wavelength tact copy can be copied again, or that the quality of this contact copy would then become extremely bad and immediately recognizable as a forgery. Before It is particularly helpful if ge is used to develop and fix the original hologram is ensured that the respective external conditions over the area of the holo  distributed are not identical. Then the color shift falls when trying to copy because of these different conditions different strength and he is un distributed over the entire hologram copy. So if care is taken that the conditions for developing and fixing the original hologram are not are the same on the entire support, the color shift is local on a copy different; Stains are then visible on the copy.

The invention creates a system in which several, preferably three masters can be used to produce a hologram. The one Individual masters are in the production of the hologram or contact holo gramms positioned in a fixed relation to each other. You can also look whole or partially overlap. It is possible for each individual master to complete the entire Image area covered, but only in a partial area ent image information holds, but these sub-areas can also overlap. In the Overlapping or overlapping areas can play colors or other effects occur or are specifically caused. It is also possible that the more ren, preferably three masters each have a different reference angle as well as a different color.

There are basically two methods available for the object material, ie to expose the film and thus create a hologram. After a first, in the most important known method, the several or three masters on each other the laid. The film or the material on which the illustration should be made. The exposure is then carried out with coherent Radiation. The different masters can have different colors and / or un have different reference angles. Furthermore, the individual masters can be different contain information and various types of information. At for example, the first master can contain individual information. Preferential The individual information is not made wise by the master himself, but by generates the coherent radiation that is modulated accordingly; accordingly  the first master is preferably a ground glass master. The second master leg preferably holds a three-dimensional hologram or a three-dimensional one Logo. The third master preferably contains a machine-readable feature. Also this can be generated in such a way that the same master is always used and that the individual, machine-readable information by modulating the coherent radiation is generated. The invention provides one possibility create individual holograms with additional constant elements, so Holograms that contain different information individually in the series to use production or mass production and thereby the advantageous Kon to apply tactical copy.

According to the second method, the several, in particular three, master holos grams in a single master hologram then exposes it for manufacture the hologram is used. This method has already been described above the.

In the system according to the invention, the series production of hologram the same master hologram, especially by means of a contact copy be used. The individual hologram can be modified by the modulated Be lighting (preferably LCD-modulated) are generated with the matte finish ben master part interacts. The three-dimensional logo is always the same and is always generated in the same way in the hologram. It reacts preferentially to a different color. The machine-readable feature can also together menu effects are generated with a focusing screen master, with a mo dulated lighting, which can be done in another color.

An embodiment of the invention will now be described with reference to the accompanying Drawing explained in detail. In the drawing shows

Fig. 1 shows the preparation of a ground glass master,

Fig. 2 shows a device for producing a hologram and

Fig. 3, the production and use of a hologram illumination.

In Fig. 1a, the production of a ground glass master is shown schematically. First, the focusing screen 1 is irradiated with laser light 2 and - as a transmission hologram - recorded on a first hologram H ₁ . For this purpose, a partial beam is coupled out of the laser beam 2 (not shown in the drawing) and directed onto the first hologram H ₁ at an angle of, for example, 45 ° as the reference beam 3 .

As can be seen from FIG. 1b, the master disc H ₂ is then produced from the first hologram H ₁ . For this purpose, the image of the focusing screen embodied therein is reconstructed from the first hologram H ₁ as a real image. This is done by irradiating the first hologram H ₁ with a laser beam 4 at an angle of 45 °. The second hologram H ₂ is located in the image plane or in the vicinity of the image plane of the first hologram H ₁ , as a result of which the focusing screen master is generated on this second hologram, specifically as a reflection hologram. As can be seen from Fig. 1b, the second hologram H ₂ by a decoupled laser beam 5 at an angle of z. B. 45 ° exposed. The second hologram H ₂ is then the master hologram of the focusing screen for the series production of the individual holograms.

Fig. 2 shows a device for producing an individual hologram with egg ner radiation source, the laser radiation 6 on a master H ₂ and a in contact with it, arranged in the beam path in front of the master H ₂ and consisting of a polymer 7 . The laser radiation 6 is modulated by a modulation device consisting of an LCD (not shown in the drawing). A stereo effect can be achieved by renewed irradiation by laser beams 6 at an angle deviating from the laser radiation 6 .

Fig. 3a shows an arrangement for using a master hologram for the produc- tion of an illumination hologram from the previously produced master hologram and in Fig. 3b an arrangement for using the illumination hologram manufactured according to Fig. 3a. A mask 10 with transparent areas 11 and opaque areas outside of these transparent areas 11 is located on a focusing screen 9 or a lenticular screen. The transparent areas 11 are arranged where hologram areas are later to be created on the holographic film.

The arrangement consisting of focusing screen 9 and mask 10 is illuminated by an object beam 12 and shines in the transparent areas 11 . A hologram 13 is arranged behind the focusing screen 9 and mask 10 in the beam direction and is illuminated by a convergent reference beam 14 . This creates the illumination hologram 13 .

This illumination hologram 13 can then be used in the manufacture of holograms. As can be seen from FIG. 3b, it is illuminated by a divergent reconstruction beam 15 , as a result of which the radiation in the image plane is mainly directed into those areas in which the cutouts 11 of the mask 10 were located.

As can be seen from FIG. 3, the laser beam used in the production of a hologram is formed by the illumination hologram 13 (illumination holograms are accordingly also referred to as beam shapers or beam shapers). By means of the illumination hologram 13 , the light energy is concentrated in those areas in which the permeable areas 11 of the mask 10 were located. When used in accordance with FIG. 3a, the mask 10 is generated as a real image 16. The arrangement is such that the real image 16 of the mask 10 arises where the LCD is located, which modulates the beam used in the production of the hologram. In this way, the selected image areas on the modulating LCD are particularly strongly illuminated or concentratedly illuminated, which leads to a significantly higher luminous efficacy. While in an uncorrected process the light yield is, for example, only 5%, with the improved process a light yield of 50% and sometimes up to 80% can be achieved, and in the dichromate process even up to 90%. With an efficiency of 50% of the hologram 13 (diffraction efficiency), 50% of the total laser power is conducted into the transparent regions 11 . This results in a significant gain in light, which in turn enables shorter exposure times to be achieved.

Claims (21)

1. Master hologram for copying a hologram in the contact process, characterized in that the master consists of several, preferably three, individual masters, each carrying different information. 2. Master according to claim 1, characterized in that the first masterholo gram is the hologram of a focusing screen. 3. Master hologram according to claim 1, characterized in that the matt pane an orderly or structured screen in the form of a lens lens sters is. 4. Master according to claim 2 or 3, characterized in that the matt screen ben master (H ₂ ) with a reflection hologram (H ₁ ) is made, which is made from a transmission hologram of a flat screen ( 1 ). 5. Master according to one of claims 2 to 4, characterized in that the focusing screen master (H ₂ ) is produced in at least two wavelengths, preferably in three wavelengths. 6. Master according to one of the preceding claims, characterized in that the second master contains constant information, preferably two se an identifier, preferably a three-dimensional identifier character. 7. Master according to one of the preceding claims, characterized in that that the third master contains a machine-readable feature. 8. Master according to one of the preceding claims, characterized in that the individual masters are exposed in a single master. 9. Master according to one of the preceding claims, characterized in that that illumination holograms are made from the master or masters. 10. Master according to claim 9, characterized in that the Ausleuchtungsho logram is produced as a computer-generated hologram (CGH). 11. Master according to claim 9, characterized in that the Ausleuchtungsho logram is produced interferometrically. 12. Device for producing an individual hologram, in particular a contact copy of a hologram ( 7 ), with a radiation source for laser radiation ( 6 , 8 ), for irradiating a master (H ₂ ) and a film ( 7 ), characterized by a modulation device , in particular an LCD, for modulating the coherent radiation ( 6 , 8 ). 13. The apparatus according to claim 12, characterized in that the master (H ₂ ) is irradiated with several, preferably two or three different wavelengths be. 14. The apparatus according to claim 12 or 13, characterized by a scanner for scanning the coherent radiation over the master and the film. 15. The device according to one of claims 12 to 14, characterized by an illumination hologram ( 13 ) for shaping the coherent radiation. 16. The apparatus according to claim 15, characterized in that the coverage hologram is a computer generated hologram (CGH). 17. The apparatus according to claim 15, characterized in that the illumination hologram ( 13 ) is produced interferometrically. 18. Device according to one of claims 12 to 17, characterized by a Color device for the colored irradiation of the master and the film, esp in particular a color-capable LCD. 19. Device according to one of claims 12 to 18, characterized by a Device for imprinting different aspect angles. 20. hologram, in particular a hologram produced using the contact process, characterized that it is with a master according to one of claims 1 to 11 and / or with egg ner device according to one of claims 12 to 19 is made. 21. Hologram according to claim 20, characterized by a color shift through the development process.