LT6114B - Holographic identity sign manufacturing method - Google Patents

Abstract

This invention relates to holography, it is the method of unique holographic sign manufacturing.Proposed the method by which the unexposed light-sensitive material (10), deposited on the flat transparent substrate is hosted on a rotational chassis and simultaneously illuminated with the coherent pulsed laser light - with and without the spatial light modulator (6), the material (10) is placed on a rotational chassis so that the rotational axis divides the material into two equal parts, the material plane is parallel to the spatial modulator (6) surface plane (7) which lies in the plane (8) and divides spatial modulator (6) into two equal parts. Material (10) is rotating at a constant angular velocity, preferably in the range from 30 to 150 degrees, at the same time spatial modulator (6), which is connected to the computer, one after another outputs the 2D images of the 3D object viewable from a different angles, the change of 2D images generated by the spatial modulator (6) and rotation angle of the material (10) is performed in such manner that it correspond to the appropriate 2D images visible from the appropriate angles in the moment of capture of 3D scene by the camera. The set of 2D images, generated by spatial modulator (6), is optically relayed and exposed to the material (10), this leads to enrolment of a certain amount of elementary holograms into material (10). When the material (10) is developed and viewed under white light, the set of recorded elementary holograms reflects a set of 2D images, each of which was taken from a different viewing angle and this angle corresponded to the angle of modulated light incidence during the holographic sign recording process, so the whole reconstructed images set viewed by observer is perceived by him as a 3D image of the subject.

Description

The present invention relates to holography and is directed to the production of unique holographic identification marks.

State of the art

Holograms, also known as optical diffractive variable devices (DOVIDs), are widely used for visual authentication of documents and products. A particularly important area of use for holograms is the use of individual documents such as passports, identity cards [ICAO, Doc 9303, Rev.3 Published 2008; COUNCIL REGULATION (EC) No 2252/2004 p.p. 5-6] and similar individual documents. Currently, such documents are usually personalized either by printing identification information over the hologram [e.g. U.S. Patent No. 7997496] or by laminating the hologram onto individual information [e.g. European Patent Application No. 09157440.0]. In both of these cases, the holograms used for all personalized documents are the same for a single series of documents. There is another known method of incorporating a photograph of an individual directly into a diffraction grid, thereby obtaining a 2D individual's face hologram directly on the document [US Patent US8059320].

Thus, all known methods of document unification perform individualization by inserting only a flat individual image into a document.

Meanwhile, a large format (A5 to 1x1.5m) digital imaging 3D holograms and device are known (e.g., US 7423792, LT4842). In this method, the spatial light modulator comprises an illuminated image formed from pixels taken from corresponding hundreds of 3D scene 2D images, the light modulator is illuminated by a coherent pulsed laser light beam, and the modulated radiation is focused by a special lens having an optical pin on its outside. a photosensitive material is placed behind the lens mount. The photosensitive material is illuminated by a pulse of modulated light along with an unmodulated support beam of laser radiation and a holographic diffractive element (HDE) is incorporated into a small area of the photosensitive material known as the holopixel or hogel. By chemically or otherwise processing (possibly self-focusing) the photosensitive material and illuminating the HDE light thus recorded with the same direction as the unmodulated laser light at the time of recording, the HDE projects the same image of a three-dimensional light modulator taken from the corresponding several hundred 3D scene 2D images so that only one pixel image is projected in each direction. Coating the entire surface of the photosensitive material with such HDEs behaves like a regular hologram - i.e. at different angles of view, slightly different parallax-linked 2D images of the same 3D scene are visible, and the brain of an observer looking at such material with two eyes perceives the visible image as spatial. Basically, this way authentication of documents is possible, but it would be inconvenient due to the long recording time of 8-10 minutes. Also, holograms made with the devices available in this way always consist of fine HDEs - so such a hologram will always have a grid structure,

The object of the present invention is to improve the process of personalizing holograms so that the individual 3D hologram is quickly and qualitatively recorded on the photosensitive material, thus opening the possibility of using the document's 3D holographic image of the holder's face or other means as a document authentication device. It should also be clear to those skilled in the art that any other 3D image associated with a particular document or batch of them could be an image used for personalization.

The essence of the invention and the operations of the proposed method

The object is achieved by employing the inventive method of recording a unique holographic identification mark, in which the unexposed photosensitive material applied to a flat transparent substrate (Material) is simultaneously illuminated by pulsed coherent laser light - unmodulated and modulated by a spatial light modulator. What's new is that the Material is placed on the torsion mechanism such that its axis of rotation divides the Material into two equal parts, is parallel to the modulator plane, and lies in a plane dividing the modulator into two equal parts,

The material rotates at a constant angular velocity in the range, preferably 30 to 150 degrees, while the computer connected to the modulator in the modulator illuminates the 2D images of the 3D object seen at that angle, for example, as shown in FIG. 6, or in other ways yielding the same results, where the 2D image conversion in the modulator and the material rotation speed are selected such that at each 2D image exposure to the Material, the Material will rotate at the angle at which the corresponding 2D image was captured (photographed or filmed), when the total energy of coherent light illuminating the Material during each exposure is greater than the lowest energy to which the Material is still sensitive and the total energy of all exposures does not exceed the energy level where the Material is almost insensitive to changes in light intensity, In a material that contains a certain number of elementary holograms, after the material has been highlighted and illuminated by white light, each of said elementary holograms restores the image of the modulated radiation to its focus during recording. direction so that the eyes of the observer looking at such Material simultaneously see two different 2D images of the 3D object and thus the person perceives the visible image as a 3D object image.

The material can be exposed to multiple wavelengths of coherent laser light simultaneously (for example, red + green + blue or another color combination) by recording a color hologram. The material can be illuminated by coherent laser beams of several wavelengths in succession (for example, red + green + blue or another color combination) by recording a color hologram.

Non-modulated radiation of coherent light can incident on the Material at a different angle during the recording of the unique hologram, allowing for better visibility of the recorded hologram in diffused light. Unmodulated coherent light radiation to the Material may fall at a constant angle relative to the normal of the Material during the recording of the unique hologram, thereby providing better visibility of the recorded hologram in the light of the point light source. Unmodulated radiation of coherent light can incident on the material during the recording of the unique hologram at variable and constant angles relative to the normal of the material, thereby providing better visibility of the recorded hologram in both spot light and diffused light.

Because all photosensitive materials have a specific sensitivity curve characterized by the fact that at low light intensities and at light intensities higher than a certain level specific to each photoelectric, the photoelectric is insensitive to changes in luminous intensity, holograms. The fact, in conjunction with the foregoing features of the present invention, wherein multiple exposures of a substance to coherent modulated and non-modulated radiation: During exposure, the material is rotated at an angle when coherent radiation is modulated, e.g., by face or other images captured or filmed at different angles. The material captures many 2D image holograms, visible at the angle at which they were captured or captured and viewed by the viewer viewing the proposed hologram as spatial, opening the document to a 3D holographic face or other image as a document authentication device.

Brief description of the drawings

FIG. 1 is a diagram illustrating a proposed method for recording a unique holographic identification mark using unmodulated coherent light emitting in a direction of normal magnitude of a Material.

Fig. 2 is a diagram (top view) explaining a proposed method for recording a unique holographic identification mark using unmodulated coherent light emitting in the direction of normal to Material.

FIG. Figure 3 is a diagram illustrating the view of a unique holographic identification mark recorded using non-modulated coherent light emitting in the direction of the normal direction of the Material.

FIG. Figure 4 is a diagram illustrating a unique holographic identification mark recorded using non-modulated, coherent beam radiation of a normal direction of the Material.

FIG. 5 is a diagram illustrating a unique holographic identification mark recorded using both unmodulated coherent light emitted by a variable and constant direction normal to the Material.

FIG. Fig. 6 is a diagram illustrating the preferred method of obtaining the images required for recording a unique holographic identification mark with a 3D portrait of the document holder.

FIG. Fig. 7 shows the image on the monitor by selecting the 3D of the holder of the unique holographic identification document and the position of the edge (left, center, and right edge of the head) images using the 3D object 2D image recording method.

DETAILED DESCRIPTION OF THE INVENTION AND APPARATUS NECESSARY FOR IMPLEMENTING THE INVENTION

In an embodiment of the proposed embodiment, the device is schematically illustrated in FIG. 1 or 2 comprises a pulsed laser 1 having a coherent radiation divider 3 with mirrors 4 positioned in the path of the coherent radiation 2 (it should be apparent to the skilled person that the mirrors 4 may be arranged in other ways) transmitting the modulated radiation through the coherent radiation formation module 5, a modulator 6 comprising a computer (not shown) rotating the material 10 and capable of sequentially emitting 2D images of a 3D object. The modulator 6 and the material 10 are arranged parallel to each other, and the modulator 6 is arranged in a plane 7 (Fig. 1). The modulator 6 and the material 10 are divided into two equal parts by a plane 8 which is perpendicular to the plane 7 (Fig. 1). At the point where the plane 8 intersects the Material 10, there is a rotation axis 11 of the Material 10 located in the path of the image transmitted from the modulator 6, the imaging-broadcasting module 9 focusing on the modulated radiation to the Material 10.

The divider 3 also transmits the unmodulated radiation to the Material 10 via a coherent radiation forming module 13, respectively arranged in a mirror system 16, 17 (Fig. 1), when these mirrors are placed on computer controlled rotation mechanisms (not shown). the axes 18 and 19 respectively being parallel to the rotational axis 11 of the material 10, and the rotational positions 20 and 21 of the mirrors 16 and 17 may be computer-controlled respectively so that unmodulated coherent radiation falls on Material 10 at constant angles 10 for normalcy. In this case, the hologram will be best seen by illuminating it with a point light source as shown in FigA. It should be apparent to those skilled in the art that mirrors 16 and 17 may also be arranged such that non-modulated coherent radiation illuminates Material 10 from the same direction as illuminated and modulated coherent radiation.

the device diagram shown in Fig. 2 differs from the diagram shown in Fig. 1 in that the unmodulated coherent radiation falls on the Material 10 reflected from the mirror 14 - that is, when the Material 10 is rotated, the angle of the unmodulated coherent radiation . In this case, the hologram will be best seen under illuminated light as shown in Fig.3.

It should be apparent to one skilled in the art that the mirror 14 may also be positioned at position 15 - the unmodulated coherent radiation would then illuminate Material 10 from the same direction as the illuminated and modulated coherent radiation.

22 2D images of a 3D object can be obtained by various known photographic or video devices, or preferably by a device shown in Fi.6. This device consists of a frame 23 (Fig.6) on which a video camera 24 is viewed facing the side of the subject and a video camera 25 placed either on the rectangular portion of the frame 23 opposite the object 22 or the video camera 26 is mounted on an optional hemispherical frame The portion 23 is opposite the object 22. The frame 23 is made to be displaced in directions 27 and 28 in the schematic plane and depending on the height of the future document holder or other object size to be imaged in the direction 29 perpendicular to the schematic plane. All camcorders are connected to a computer (not shown), the center and edge cameras from camcorders 25 or 26, and an image from cam 24 are output to a monitor (not shown).

Position 30 is the optical axis of the cameras 25 or 26 and its intersection lies in a plane perpendicular to the schematic plane and passing through the optical axis 31 of the camcorder 24. This plane provides the image plane of a unique holographic mark.

Implementation of the Invention

The pulsed laser 1 provides coherent radiation 2, (Fig. 1 or Fig. 2) to a coherent radiation divider 3. The intensity of each coherent radiation can then be changed by standard optical means (not shown), after which the coherent radiation 2 is divided and directed to the coherent radiation. forming modules 5 and 13, respectively, to form a coherent beam for illumination of the light modulator 6 and to form a coherent beam such that it fully illuminates Material 10. The material may be, for example, silver halide-based materials - VRP-M, PFG -03C, GEO-3 and the like, photopolymeric materials such as DuPont Photopolymer, Bayfol HX photopolymer, Polygram DAROL Photopolymer, photoresist materials such as Microposit S 1800 Series Photoresist, colloidal photoresist materials and the like. The modulator may be, for example, a Holoeye LC 2012. (It should be apparent to one skilled in the art that a reflection type modulator may be used instead of the bandwidth type modulator 6 shown in the diagrams. In addition, various combinations of modulators may be used for color hologram recording. in essence.

By recording a unique holographic identification mark, the Material can be illuminated by both single and multiple color coherent laser beams simultaneously to record a color hologram, e.g. 440 nm, 532 nm, and 660 nm, or radiation with other wavelengths (see Fig. Evangelos Mirlis et al., Selection of Optimum Wavelengths for Holography Recording, Proc. SPIE 5742, Practical Holography XIX: Materials and Applications, 113 (May 05) , 2005); doi: 10.1117 / 12.583224).

After modulator 6, the modulated coherent radiation enters the imaging-broadcasting module 9, by means of which the reduced image transmitted in the light modulator is transmitted to the Material 10 placed on the rotating mechanism as described above.

According to FIG. Figure 6 illustrates the device for obtaining 22 2D images of a 3D object. The cameras 25 or 26 are oriented so that their axes 30 intersect at one point. The axis of the central video camera from the cameras 25 or 26 must be parallel to the direction 27. The video camera 24 is oriented so that its axis 31 is perpendicular to the direction 27 and passes through the intersection of the axes 30. The plane passing through axis 31 and perpendicular to the outline of the diagram provides the image plane of a unique holographic sign. As mentioned above, all camcorders are connected to a computer (not shown in the diagram), the image from the center and edge camcorders from camcorders 25 or 26, and the image from the camcorder 24 are output to a monitor (not shown). Frame 23 is rotated in directions 28 and 29 such that the 3D object is centered on the center and edge of the video cameras 32 or 32 of the video cameras 25 or 26 (Fig.7). Frame 23 is rotated in direction 27 so that 3D object image 33 (Fig.7) is intersected at line 34, thereby selecting the desired 3D document holder 3D holographic image, where line 34 represents zero object coordinate of image with unique holographic image the plane is identical to the plane of the document. From line 34 toward the nose, the image of the unique holographic mark will be observed as hanging in space above the document plane, and from line 34 toward the back of the line, the image of the unique holographic mark will be tracked into the depth of the hologram.

Once the required holographic image of the future document holder or other 3D object has been set, the computer saves all camera 25 (or 26) images for changing the position of the frame 23 relative to the document holder face or 3D object, .

Before the unique holographic mark is recorded, Material 10 is rotated at an angle minus 15 + 75 or plus 15 + 75 degrees relative to the plane of the modulator 6.

During the unique holographic inscription, Material 10 is rotated at a constant angular speed to plus 15 + 75 or minus 15 + 75 degrees to modulator 6, relative to plane 7, depending on whether its initial position was minus 15 + 75 or plus 15 + 75 degrees. of modulator 6 with respect to plane 7. During rotation of the material 10, with each pulse laser pulse, the modulator 6 illuminates different 3D scene 2D images available in the modulator computer (obtained according to Fig. 6 above) corresponding to the angle at which the material 10 is rotated with respect to the plane 7 of the modulator. . The direction of rotation of the material 10 should correspond to the sequence of images illuminated by the modulator 6. The rotation speed of the material 10 is selected such that during each 2D image exposure of the material 10, the material 10 rotates at the angle at which the 2D image was imaged (photographed or filmed, e.g. , described above in Figure 6).

The system of rotating mirrors 16 and 17 (Fig. 1) is used to record a unique holographic mark, better visible in the spot source light. These mirrors are placed on computer controlled rotation mechanisms (not shown) so that their rotational axes are parallel to the rotational axis 11 of the material 10, and the rotational positions 20 and 21 of the mirrors 16 and 17 are selected such that unmodulated coherent radiation falls at each pulse of coherent radiation. to Material 10 at an angle constant to Material 10 normal. It should be apparent to one skilled in the art that mirrors 16 and 17 (Fig. 1) may also be arranged such that unmodulated coherent radiation illuminates Material 10 from the same direction as modulated coherent radiation. To record the unique holographic mark seen in diffused light, FIG. 2 illustrates a system where the material 10 rotates illuminates the material 10 at a variable angle relative to the normal of the material 10 in unmodulated coherent radiation.

The coherent radiation shaping module 13, which shapes the unmodulated coherent radiation so that it fully illuminates Material 10, also forms the desired wavefront incident on the Material

10, which determines the desired distance between the unique inscribed holographic mark and the light source required for its observation. For example, it is possible to illuminate the Material with a slightly diffused beam of coherent light, while approximating the location of the light source needed for hologram tracking to the hologram.

For each exposure, the total energy of the coherent light illuminating Material 10 is greater than the minimum energy for which Material 10 is still sensitive, and the total energy of all exposures does not exceed the energy level when Material 10 is almost insensitive to changes in light intensity. It should be clear that the exposure conditions of this Substance 10 may vary slightly depending on the specific properties of the Substance 10. It should be clear to those skilled in the art that the distribution of radiant energy beams can be either Gaussian or II. It should also be clear to those skilled in the art that the proposed method may be incorporated into a system, such as an automated line recording individual holograms into appropriately prepared blanks, which may also be coated with photosensitive material.

After the Material 10 has been highlighted and illuminated by white light, each of said elementary holograms restores a modulated radiation image in focus in the direction of recording so that the eyes of the observer looking at such Material simultaneously see two different 2D images of the 3D object and in this way the person would perceive the visible image as a 3D object image. This yields a unique holographic identification mark on Material 10.

If Material 10 is illuminated from unmodulated radiation on the opposite side to that illuminated by modulated radiation (through mirrors 14, 16, 17 in Figure 1, or through mirror 14 in Figure 2), unique holographic marks are visible when illuminated from the side of Material 10, illuminated by unmodulated radiation.

If Material 10 is illuminated by unmodulated radiation from the same side as it is illuminated by modulated radiation (through the rotating mirrors 16, 17, or 2, respectively, of mirror Fig. 15), unique holographic characters are visible when illuminated. they are coherent with the corresponding laser beam from the side of Material 10 illuminated by modulated radiation.

It should be clear to those skilled in the art that not only the newly formed individual holographic mark, but also the primary hologram on a flat base may be seen after highlighting.

Modulated and unmodulated coherent light radiation can

10 intersect in photosensitive Material 10 on the same or opposite sides, thus recording both the transmittance and the reflection hologram.

Substance 10 may be illuminated by multiple color coherent laser beams, such as 440nm, 532nm and 660nm, or other wavelengths, by recording a unique holographic identification mark (see Fig. 15, Selection of optimum vvavelengths by Evangelos Mirlis et al. recording, Proc. SPIE 5742, Practical Holography XIX: Materials and Applications, 113 (May 05, 2005); doi: 10.1117 / 12.583224), recording a color hologram.

The material 10 may be illuminated by the aforementioned multiple color coherent laser beams with the unique holographic identification mark 20 and also a color hologram.

The unmodulated radiation of coherent light may incident on the Material during the recording of the unique hologram at an angle constant with respect to the normal of the Material as shown in FIG. 1, thereby providing better visibility of the recorded hologram in the light of a point light source according to FIG. 4. FIG. In the diagram shown in Figure 4, Material 10 illuminates the point source light 38 and the 2D images 36 of the 3D object depicted in the elementary holograms are visible at the angles at which they were depicted, resulting in the viewer 37 perceiving the visible image as a 3D image of the 3D object. Unmodulated radiation of coherent light may incident on the Material during the recording of the unique hologram at an angle variable with respect to the normal of the material, as shown in Figs. 2, thereby providing better visibility of the recorded hologram in diffused light according to FIG. 3. FIG. In the diagram shown in Figure 3, Material 10 is illuminated by diffused light 35 and 2D images 36 of the 3D object depicted in the elementary holograms 11 are visible at the angles at which they were depicted - resulting in the viewer 37 perceiving the visible image as a 3D image of the 3D object.

Unmodulated coherent light radiation may incident on the Material during the recording of the unique hologram and alternate and constant directions of the Material normal, thereby providing better visibility of the recorded hologram in both spot light and diffused light, as shown in FIG. 5. In the diagram shown in Figure 5, Material 10 illuminates and diffuses light 35 and dot source light 38 - 2D images 36 of the 3D object depicted in elementary holograms are viewed at the angles at which they are depicted, resulting in viewer 37 perceiving the visible image as a 3D image of the 3D object.

It should be apparent to one skilled in the art that Figures 1 and 2 show only one, simplest arrangement of equipment for recording a single color unique holographic sign, and the presented diagrams may be obviously modified by the addition of multiple color lasers, appropriate optical components, or document personalization line.

Additionally, when recording a unique holographic identification mark, it should be clear to those skilled in the art that, depending on the type of photo-sensitive layer of the Material, the Material may be additionally illuminated by coherent laser light and / or UV lamp and / or other non-coherent light source. such as thermal.

As mentioned above, all photosensitive materials have a certain sensitivity curve, which is characterized by the fact that at low light intensities and at light intensities above a certain level specific to each photomaterial, the photomaterial is almost insensitive to changes in light intensity; several holograms visible at different angles to the Material. This fact, in conjunction with the foregoing features of the invention, wherein the Material is repeatedly exposed to coherent modulated and unmodulated radiation; rotating the subject at an angle when the coherent radiation is modulated, such as face or other images shot or filmed at different angles, resulting in a large number of 2D image holograms visible at the angle at which they were captured and viewed by the viewer perceived as spatial, the proposed hologram opens the possibility of using a document's 3D holographic face or other image as a means of document authentication.

It should be noted that the proposed method is significantly faster than the nearest analogs described in US 7423792; LT4842, using a 30 Hz pulsed laser and a recorded hologram resolution of 100x150 pixels (hologram size 1x1.5 cm, holographic pixel size 0.1 mm), these techniques would allow recording an individual 10x15 mm 5 size hologram in 8.25 minutes. Meanwhile, the proposed method allows for recording a hologram of this size with an image resolution of at least 640x480 pixels using the same laser and 48 parallax-linked 3D object images within 1.6 seconds.

Claims (8)

Definition of the Invention 1. A method of producing a unique holographic identification mark by exposing a non-exposed photosensitive material on a flat, transparent substrate (Material) to simultaneously illumination by pulsed coherent laser light, unmodulated and modulated by a spatial light modulator, characterized in that the Material (10). ) is placed on the torsion mechanism such that its axis of rotation divides the Material (10) into two equal parts, is parallel to the plane (7) of the modulator (6) and lies in the plane (8) dividing the modulator (6) into two equal parts, - The material (10) is rotated at a constant angular velocity in the range, preferably 30 to 150 degrees, while simultaneously a computer connected to the modulator (6) in the modulator (6) illuminates the 2D images of the 3D object, as shown in Figs. 6, when the 2D image conversion in the modulator (6) and the rotation speed of the Material (10) are selected such that during each exposure of the 2D image to the Material (10), the Material (10) is rotated at the angle at which the respective 2D image was displayed. during exposure, the total energy of the coherent light illuminating the Material (10) is greater than the lowest energy to which the Material (10) is still sensitive, and the total energy of all exposures does not exceed energy when Material (10) is almost insensitive to changes in light intensity; - in the modulator (6), the broadcast system (9) focuses the image on the Material (10) from the illuminated image-forming system, whereby a number of elementary holograms are recorded, after the material (10) is highlighted and illuminated by white light; The viewer then focuses on the image of the modulated radiation in the direction of its recording so that the eyes of the observer looking at such Material (10) simultaneously see two different 2D images of the 3D object and thereby perceive the visible image as a 3D object image. 2. A method according to claim 1, characterized in that the Material (10) is illuminated by radiation of several wavelengths, for example a combination of red, green and blue, simultaneously recording a colored hologram. 3. A method as claimed in claim 1, characterized in that the Material (10) is illuminated by radiation of several wavelengths, for example a combination of red, green and blue radiation, successively recording a colored hologram. 4. A method as claimed in claims 1 to 3, characterized in that the unmodulated radiation of the coherent light falls to the Material during the recording of the unique hologram at a variable angle to the Normal of the Material (10) thereby providing better visibility of the recorded hologram in diffused light. 5. A method as claimed in claims 1 to 3, wherein the unmodulated coherent light incident on the Material (10) falls at a constant angle to the Material (10) during recording of the unique hologram, thereby providing better visibility of the recorded hologram in a point light source. 6. A method according to claims 1-3, wherein the unmodulated radiation of coherent light falls on the Material (10) during the recording of a unique hologram at both variable and constant angles to the normal of the Material (10), thereby providing better visibility of the recorded hologram. both in source light and diffused light. A unique holographic identification mark obtained by the method of claims 1-6. The mark of claim 7 for use as a document or product authentication device.