WO2005052650A2 - Micro-optic security and image presentation system - Google Patents
Micro-optic security and image presentation system Download PDFInfo
- Publication number
- WO2005052650A2 WO2005052650A2 PCT/US2004/039315 US2004039315W WO2005052650A2 WO 2005052650 A2 WO2005052650 A2 WO 2005052650A2 US 2004039315 W US2004039315 W US 2004039315W WO 2005052650 A2 WO2005052650 A2 WO 2005052650A2
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- image
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Classifications
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- G02B30/20—Optical systems or apparatus for producing three-dimensional [3D] effects, e.g. stereoscopic images by providing first and second parallax images to an observer's left and right eyes
- G02B30/26—Optical systems or apparatus for producing three-dimensional [3D] effects, e.g. stereoscopic images by providing first and second parallax images to an observer's left and right eyes of the autostereoscopic type
- G02B30/27—Optical systems or apparatus for producing three-dimensional [3D] effects, e.g. stereoscopic images by providing first and second parallax images to an observer's left and right eyes of the autostereoscopic type involving lenticular arrays
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B41—PRINTING; LINING MACHINES; TYPEWRITERS; STAMPS
- B41M—PRINTING, DUPLICATING, MARKING, OR COPYING PROCESSES; COLOUR PRINTING
- B41M3/00—Printing processes to produce particular kinds of printed work, e.g. patterns
- B41M3/14—Security printing
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- B42D2033/24—
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- B42D2035/08—
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- B42D2035/20—
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- B42D2035/44—
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- D—TEXTILES; PAPER
- D21—PAPER-MAKING; PRODUCTION OF CELLULOSE
- D21H—PULP COMPOSITIONS; PREPARATION THEREOF NOT COVERED BY SUBCLASSES D21C OR D21D; IMPREGNATING OR COATING OF PAPER; TREATMENT OF FINISHED PAPER NOT COVERED BY CLASS B31 OR SUBCLASS D21G; PAPER NOT OTHERWISE PROVIDED FOR
- D21H21/00—Non-fibrous material added to the pulp, characterised by its function, form or properties; Paper-impregnating or coating material, characterised by its function, form or properties
- D21H21/14—Non-fibrous material added to the pulp, characterised by its function, form or properties; Paper-impregnating or coating material, characterised by its function, form or properties characterised by function or properties in or on the paper
- D21H21/40—Agents facilitating proof of genuineness or preventing fraudulent alteration, e.g. for security paper
- D21H21/44—Latent security elements, i.e. detectable or becoming apparent only by use of special verification or tampering devices or methods
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10—TECHNICAL SUBJECTS COVERED BY FORMER USPC
- Y10T—TECHNICAL SUBJECTS COVERED BY FORMER US CLASSIFICATION
- Y10T29/00—Metal working
- Y10T29/49—Method of mechanical manufacture
- Y10T29/49826—Assembling or joining
Definitions
- the present invention relates to a synthetic magnification micro-optic system that in an exemplary embodiment is formed as a polymer film.
- the unusual optical effects provided by the various embodiments of the disclosure can be used as a security device for overt and covert authentication of currency, documents, and products as well as visual enhancement of products, packaging, printed material, and consumer goods.
- Background Various optical materials have been employed to provide authentication of currency and documents, to identify and distinguish authentic products from counterfeit products, and to provide visual enhancement of manufactured articles and packaging. Examples include holographic displays, and other image systems involving lenticular structures and arrays of spherical micro-lenses.
- lenticular structure for document security is disclosed in U.S. Patent 4,892,336 to Kaule, et al. directed to a security thread for embedding within a document to provide anti-falsification measures.
- the security thread is transparent having a printed pattern on one side, on the opposite side, a lenticular lens structure coordinated with the printed pattern.
- the lenticular lens structure is described as comprised of a plurality of parallel cylinder lenses, or alternatively spherical or honeycomb lenses.
- a security device that includes an array of micro-images coupled with an array of substantially spherical micro-lenses.
- the lenses may also be astigmatic lenses.
- the lenses are each typically 50-250 ⁇ m and with a focal length of typically 200 ⁇ m.
- the present disclosure relates to a film material that utilizes a regular two- dimensional array of non-cylindrical lenses to enlarge micro-images, called icons herein, and to form a synthetically magnified image through the united performance of a multiplicity of individual lens/icon image systems.
- the synthetically magnified images and the background surrounding them can be either colorless or colored, and either or both the images and the background surrounding them can be transparent, translucent, pigmented, fluorescent, phosphorescent, display optically variable color, metallized, or substantially retroreflective.
- the material displaying colored images on a transparent or tinted background is particularly well suited for use in combination with underlying printed information.
- a piece of such material is applied over printed information both the printed information and the images are seen at the same time in spatial or dynamic motion relationship to each other.
- Material of this kind can also be overprinted, i.e. have print applied to the uppermost (lens) surface of the material.
- the material displaying colored images (of any color, including white and black) on a translucent or substantially opaque background of different color is particularly well suited for stand-alone use or with overprinted information, not in combination with underlying printed information.
- the magnitude of the synthetic magnification achieved can be controlled by the selection of a number of factors, including the degree of 'skew' between the axes of symmetry of the lens array and the axes of symmetry of the icon array.
- Regular periodic arrays possess axes of symmetry that define lines that the pattern could be reflected around without changing the basic geometry of the pattern, that in the ideal of arrays are infinite in extent.
- a square array for example, can be reflected around any diagonal of any square without changing the relative orientation of the array: if the sides of the squares are aligned with the x and y axes of the plane, then the sides of the squares will still be aligned with those axes after reflection, with the assumption that all sides are identical and indistinguishable.
- the array can be rotated through an angle equal to the angle between the axes of symmetry of the same type.
- the array can be rotated through an angle of 90 degrees, the angle between diagonals, to arrive at an array orientation which is indistinguishable from the original array.
- an array of regular hexagons can be mirrored or rotated about a number of axes of symmetry, including the "diagonals" of the hexagon (the lines connecting opposite vertices) or "midpoint divisors" (lines that connect between the center points of faces on opposite sides of the hexagon).
- the angle between the axes of symmetry of either type is sixty degrees (60°) results in an array orientation that is indistinguishable from the original orientation.
- a lens array and an icon array are initially arranged with their planar dimensions defining their respective x-y plane, one of the axes of symmetry being chosen to represent the x axis of the first array, the corresponding type of axis of symmetry (for example, diagonal axis of symmetry) being chosen to represent the x axis of the second array, with the two arrays separated by a substantially uniform distance in the z axis direction, then the arrays are said to have zero skew if the x axes of the arrays appear to be parallel to each other when the arrays are viewed along the z axis direction.
- Unison Deep and SuperDeep present images that appear to rest on a spatial plane that is visually deeper than the thickness of the material.
- Unison Float and SuperFloat present images that appear to rest on a spatial plane that is a distance above the surface of the material; and Unison Levitate presents images that oscillate from Unison Deep (or SuperDeep) to Unison Float (or SuperFloat) as the material is rotated through a given angle (e.g. 90 degrees), then returning to Unison Deep (or SuperDeep) again as the material is further rotated by the same amount.
- Unison Morph presents synthetic images that change form, shape, or size as the material is rotated or viewed from different viewpoints.
- Unison 3-D presents images that show large scale three-dimensional structure, such as an image of a face.
- Multiple Unison effects can be combined in one film, such as a film that incorporates multiple Unison Motion image planes that can be different in form, color, movement direction, and magnification.
- Another film can combine a Unison Deep image plane and a Unison Float image plane, while yet another film can be designed to combine Unison Deep, Unison Motion, and Unison Float layers, in the same color or in different colors, those images having the same or different graphical elements.
- the total thickness of the film be less than 50 microns, (also referred to herein as " ⁇ ", or “um"), for example less than about 45 microns, and as a further example in the range of about 10 microns to about 40 microns. This can be accomplished, for example, through the use of focusing elements having an effective base diameter of less than 50 microns, as a further example less than 30 microns, and as yet a further example, from about 10 microns to about 30 microns.
- a focusing element having a focal length of less than about 40 microns can be used.
- focusing elements having a base diameter of 35 microns and a focal length of 30 microns can be used.
- An alternate, hybrid refractive/diffractive embodiment can be made as thin as 8 microns.
- the films herein are highly counterfeit resistant because of their complex multi-layer structure and their high aspect-ratio elements that are not amenable to reproduction by commonly available manufacturing systems.
- the present system provides a micro-optic system preferably in the form of a polymer film having a thickness that when viewed by unaided eye(s) in reflective or transmitted light projects one or more images that: i. show orthoparallactic movement (Unison Motion); ii. appear to lie on a spatial plane deeper than the thickness of the polymer film (Unison Deep and Unison SuperDeep); iii. appear to lie on a spatial plane above a surface of the polymer film (Unison Float and Unison SuperFloat); iv. oscillate between a spatial plane deeper than the thickness of the polymer film and a spatial plane above a surface of the film as the film is azimuthally rotated (Unison Levitate); v.
- Unison Motion orthoparallactic movement
- iii. appear to lie on a spatial plane above a surface of the polymer film Unison Float and Unison SuperFloat
- the present disclosure more particularly provides a synthetic magnification micro-optic system and method of making the same comprising: (a) one or more optical spacers; (b) a micro image comprised of a periodic planar array of a plurality of image icons having an axis of symmetry about at least one of its planar axes, and positioned on or next to the optical spacer; and (c) a periodic planar array of image icon focusing elements having an axis of symmetry about at least one of its planar axes, the axis of symmetry being the same planar axis as that of the micro image planar array, each focusing element being either a polygonal base multi-zonal focusing element, a lens providing an enlarged field of view over the width of the associated image icon so that the peripheral edges of the associated image icon do not drop out of view, or an aspheric focusing element having an effective diameter of less than 50 microns.
- the system can include one or more of the aforementioned effects.
- a method is provided by which said effects can be selectively included within the system.
- the present disclosure further provides a security device suitable for at least partial incorporation in or on, and for use on or in association with, a security document, label, tear tape, tamper indicating device, sealing device, or other authentication or security device, which comprises at least one micro-optic system, as defined above.
- a document security device and method of making the same comprising: (a) one or more optical spacers; (b) a micro image comprised of a periodic planar array of a plurality of image icons having an axis of symmetry about at least one of its planar axes, and positioned on or next to the optical spacer; and (c) a periodic planar array of image icon focusing elements having an axis of symmetry about at least one of its planar axes, the axis of symmetry being the same planar axis as that of the micro image planar array, each focusing element being either a polygonal base multi-zonal focusing element, a lens providing an enlarged field of view over the width of the associated image icon so that the peripheral edges of the associated image icon do not drop out of view, or an aspheric focusing element having an effective diameter of less than 50 microns.
- the present disclosure provides a visual enhancement device which comprises at least one micro-optic system, as defined above and having the above described effects, for visual enhancement of clothing, skin products, documents, printed matter, manufactured goods, packaging, point of purchase displays, publications, advertising devices, sporting goods, financial documents and transaction cards, and all other goods.
- a security document or label having at least one security device, as defined above, at least partially embedded therein and/or mounted thereon.
- Fig. 1 a is a cross-section of a micro-optic system exemplifying one embodiment of the present disclosure providing orthoparallactic movement of the images of the system.
- Fig. lb is an isometric cutaway view of the embodiment of Fig. la.
- Fig. 2a illustrates an orthoparallactic synthetic image motion effect of the embodiment of Figs. la-b.
- Figs. 2 b-c illustrate the visual effects of the Deep and Float embodiments of the present system.
- Figs. 2 d-f illustrate the visual effects obtained by rotation of a Levitate embodiment of the present system.
- Figs. 1 a is a cross-section of a micro-optic system exemplifying one embodiment of the present disclosure providing orthoparallactic movement of the images of the system.
- Fig. lb is an isometric cutaway view of the embodiment of Fig. la.
- Fig. 2a illustrates an orthoparallactic synthetic image motion effect of the embodiment of Figs
- FIG. 3 a-i are plan views showing various embodiments and fill-factors of different patterns of symmetric two dimensional arrays of lenses of the present system.
- Fig. 4 is a graph illustrating different combinations of Deep, Unison, Float, and Levitate embodiment effects produced by variation of the icon element period/lens period ratio.
- Figs. 5 a-c are plan views illustrating how the synthetic magnification of the icon images can be controlled by the relative angle between the lens array and icon array axes of the present system.
- Figs. 6 a-c are plan views illustrating an embodiment accomplishing a morphing effect of synthetically magnified images of the present system.
- Figs. 7 a-c are cross-sections showing various embodiments of the icon layer of the present system.
- Fig. 8 a-b are plan views illustrating both 'positive' and 'negative' icon element embodiments.
- Fig. 9 is a cross-section view illustrating an embodiment of a multi-level material for creating regions of a synthetically magnified image having different properties.
- Fig. 10 is a cross-section view illustrating another embodiment of a multi-level material for creating regions of a synthetically magnified image having different properties.
- Figs. 11 a-b are cross-section views showing reflective optics and pinhole optics embodiments of the present system.
- Figs. 12 a-b are cross-section views comparing the structures of an all- refractive material embodiment with a hybrid refractive/reflective material embodiment.
- FIG. 13 is a cross-section view showing a 'peel-to-reveal' tamper-indicating material embodiment.
- Fig. 14 is a cross-section view illustrating a 'peel-to-change' tamper-indicating material embodiment.
- Figs. 15 a-d are cross-section views showing various embodiments of two- sided systems.
- Figs. 16 a-f are cross-section views and corresponding plan views illustrating three different methods for creating grayscale or tonal icon element patterns and subsequent synthetically magnified images by the present system.
- Figs. 17 a-d are cross-section views showing the use of the present system in conjunction with printed information. Figs.
- FIGS. 18 a-f are cross-section views illustrating the application of the present system to, or inco ⁇ oration into, various substrates and in combination with printed information.
- Figs. 19 a-b are cross-section views comparing the in- focus field of view of a spherical lens with that of a flat field aspheric lens when each are inco ⁇ orated into the present system.
- Figs. 20 a-c are cross-section views illustrating two benefits of utility which result from the use of a thick icon layer in the present system.
- Fig. 21 is a plan view that shows the application of the present system to currency as a "windowed" security thread.
- Fig. 22 illustrates the orthoparallactic motion embodiment of the present system of images in connection with a "windowed" security thread.
- Fig. 23 illustrates half-toning a synthetic image of the present system.
- Fig. 24a illustrates use of the present system to create combined synthetic images that are smaller in dimension than the smallest feature of the individual synthetic images.
- Fig. 24b illustrates use of the present system to create narrow patterns of gaps between icon image elements.
- Fig. 25 illustrates inco ⁇ oration of covert, hidden information into icon images of the present system.
- Fig. 26 illustrates creating fully three-dimensional images with the present system.
- Fig. 27 illustrates the method for designing icon images for the three- dimensional embodiment of Fig. 26.
- Fig. 28 illustrates the icon image resulting from the method of Fig. 27.
- Fig. 29 illustrates how the method of Fig. 27 can be applied to a complex three-dimensional synthetic image.
- Fig. 30 illustrates the central zone focal properties of an exemplary hexagonal base multi-zonal lens having an effective diameter of 28 microns.
- Fig. 31 illustrates the central zone focal properties of a spherical lens having a diameter of 28 microns.
- Fig. 32 illustrates the performance of the side zones of the hexagonal lens of
- Fig. 33 illustrates the performance of the outer zones of the spherical lens of Fig. 31.
- Fig. la illustrates one embodiment of the present micro-optic system 12 providing orthoparallactic movement of the images of the system.
- the system 12 micro-lenses 1 that have at least two substantially equal axes of symmetry and that are arranged in a two-dimensional periodic array.
- Lens diameter 2
- Micro-lens 1 focuses an image of icon element 4 and projects this image 10 toward a viewer.
- the system is commonly used in situations having normal levels of ambient lighting, so the illumination of the icon images arises from reflected or transmitted ambient light.
- Icon element 4 is one element of a periodic array of icon elements having periods and dimensions substantially similar to those of the lens array including lens 1.
- an optical spacer 5 which may be contiguous with the lens 1 material or may optionally be a separate substrate 8 - in this embodiment the lenses 9 are separate from the substrate.
- the icon elements 4 may be optionally protected by a sealing layer 6, preferably of a polymer material.
- Sealing layer 6 may be transparent, translucent, tinted, pigmented, opaque, metallic, magnetic, optically variable, or any combination of these that provide desirable optical effects and/or additional functionality for security and authentication pu ⁇ oses, including support of automated currency authentication, verification, tracking, counting and detection systems, that rely on optical effects, electrical conductivity or electrical capacitance, magnetic field detection.
- the total thickness 7 of the system is typically less than 50 ⁇ ; the actual
- the thickness depends on the F# of the lenses 1 and the diameter of the lenses 2, and the thickness of additional security feature or visual effect layers.
- the repeat period 11 of the icon elements 4 is substantially identical to the repeat period of the lenses 1 ; the "scale ratio", the ratio of the repeat period of the icons to the repeat period of the lenses, is used to create many different visual effects.
- Axially symmetric values of the scale ratio substantially equal to 1.0000 result in Unison Motion orthoparallactic effects when the symmetry axes of the lenses and the icons are misaligned
- axially symmetric values of the scale ratio less than 1.0000 result in Unison Deep and Unison SuperDeep effects when the symmetry axes of the lenses and the icons are substantially aligned
- axially symmetric values of the scale ratio greater than 1.0000 result in Unison Float and Unison SuperFloat effects when the symmetry axes of the lenses and the icons are substantially aligned.
- Axially asymmetric values of the scale ratio such as 0.995 in the X direction and 1.005 in the Y direction, result in Unison Levitate effects.
- Unison Mo ⁇ h effects can be obtained by scale distortions of either or both the lens repeat period and the icon repeat period, or by inco ⁇ orating spatially varying information into the icon pattern.
- Unison 3-D effects are also created by inco ⁇ orating spatially varying information into the icon pattern, but in this embodiment the information represents different viewpoints of a three dimensional object as seen from specific locations substantially corresponding to the locations of the icons.
- Fig. lb presents an isometric view of the present system, as depicted in cross- section in Fig. la, having square array patterns of lenses 1 and icons 4 of repeat period 11 and optical spacer thickness 5 (Fig. la is not specific to a square array pattern, but is a representative cross-section of all regular periodic array patterns).
- the icon elements 4 are shown as "$" images, clearly seen in the cut-away section at the front. While there is substantially a one-to-one correspondence between lenses 1 and icon elements 4, the axes of symmetry of the lens array will not, in general, be exactly aligned with the axes of symmetry of the icon array. In the case of the Unison (orthoparallactic motion) material embodiment of Figs, la-b with a scale ratio of 1.0000, when the lens 1 axes and icon elements 4 axes are substantially aligned, the resulting synthetic images of the icon elements (in this example, a giant "$”) "blow-up" and are magnified by a factor that theoretically approaches infinity.
- the synthetic magnification factor of Unison Deep, Unison Float, and Unison Levitate embodiments depends on the angular alignment of the lens 1 axes and the icon elements 4 axes as well as the scale ratio of the system. When the scale ratio is not equal to 1.0000 the maximum magnification obtained from substantial alignment of these axes is equal to the absolute value of 1/(1.0000 - (scale ratio)). Thus a Unison Deep material having a scale ratio of 0.995 would exhibit a maximum magnification of 11/(1.000 - 0.995)
- 200x.
- a Unison Float material having a scale ratio of 1.005 would also exhibit a maximum magnification of 11/(1.000 - 1.005)
- 200x.
- slight angular misalignment of the lens 1 axes and icon elements 4 axes of the Unison Deep, Unison Float, and Unison Levitate embodiments reduces the magnification factor of the synthetic images of the icon elements and causes the magnified synthetic images to rotate.
- Fig. 2a schematically depicts the counter-intuitive orthoparallactic image motion effects seen in the Unison Motion embodiment.
- the left side of Fig. 2a depicts a piece of Unison Motion material 12 in plan view being oscillated 18 about horizontal axis 16. If the synthetically magnified image 14 moved according to parallax, it would appear to be displaced up and down (as shown in Fig.
- FIG. 2a depicts a perspective view of a piece of material 12 exhibiting the orthoparallactic motion of a single synthetically magnified image 14 as it is oscillated 18 about horizontal rotational axis 16.
- the dotted outline 22 shows the position of the synthetically magnified image 14 after it has moved to the right by orthoparallaxis and the dotted outline 24 shows the position of the synthetically magnified image 14 after it has moved to the left by orthoparallaxis.
- the visual effects of the Unison Deep and Unison Float embodiments are isometrically depicted in Figs. 2 b,c.
- Fig. 2b a piece of Unison Deep material 26 presents synthetically magnified images 28 that stereoscopically appear to lie beneath the plane of the Unison Deep material 26 when viewed by the eyes of the observer 30.
- Fig. 2b a piece of Unison Deep material 26 presents synthetically magnified images 28 that stereoscopically appear to lie beneath the plane of the Unison Deep material 26 when viewed by the eyes of the observer 30.
- a piece of Unison Float material 32 presents synthetically magnified images 34 that stereoscopically appear to lie above the plane of the Unison Float material 34 when viewed by the eyes of the observer 30.
- the Unison Deep and Unison Float effects are visible from all azimuthal viewing positions and over a wide range of elevation positions, from vertical elevation (such that the line of sight from the eyes of the observer 30 to the Unison Deep material 26 or Unison Float material 32 is pe ⁇ endicular to the surface of the materials) down to a shallow elevation angle which is typically less than 45 degrees.
- the visibility of the Unison Deep and Unison Float effects over a wide range of viewing angles and orientations provides a simple and convenient method of differentiating Unison Deep and Unison Float materials from simulations utilizing cylindrical lenticular optics or holography.
- the Unison Levitate embodiment effect is illustrated in Figs. 2 d-f by isometric views showing the stereoscopically perceived depth position of a synthetically magnified image 38 in three different azimuthal rotations of the Unison Levitate material 36 and the co ⁇ esponding plan view of the Unison Levitate material 36 and synthetically magnified image 38 as seen by the eyes of the observer 30.
- Fig. 2 d-f isometric views showing the stereoscopically perceived depth position of a synthetically magnified image 38 in three different azimuthal rotations of the Unison Levitate material 36 and the co ⁇ esponding plan view of the Unison Levitate material 36 and synthetically magnified image 38 as seen by the eyes of the observer 30.
- FIG. 2d depicts the synthetically magnified image 38 (hereafter referred to as 'the image') as stereoscopically appearing to lie in a plane beneath the Unison Levitate material 36 when said material is oriented as shown in the plan view.
- the heavy dark line in the plan view serves as an azimuthal orientation reference 37 for the sake of explanation.
- the orientation reference 37 is aligned in a vertical direction and the image 38 is aligned in a horizontal direction.
- the image 38 appears in the Unison Deep position because the scale ratio is less than 1.000 along a first axis of the Unison Levitate material 36 that is aligned substantially parallel to a line connecting the pupils of the observer's two eyes (this will be hereafter called the 'stereoscopic scale ratio').
- the stereoscopic scale ratio of the Unison Levitate material 36 is greater than 1.000 along a second axis pe ⁇ endicular to this first axis, thereby producing a Unison Float effect of the image 38 when the second axis is aligned substantially parallel to a line connecting the pupils of the observer's eyes, as shown in Fig. 2f.
- the orientation reference 37 is in a horizontal position in this figure.
- Fig. 2e depicts an intermediate azimuthal orientation of the Unison Levitate material 36 that produces a Unison Motion orthoparallactic image effect because the stereoscopic scale ratio in this azimuthal orientation is substantially 1.000.
- the visual effect of a Unison Levitate image 38 moving from beneath the Unison Levitate material 36 (Fig.
- the shadow images produced do move. Furthermore, while the Unison synthetic images may lie in different visual planes than the plane of the material, the shadow images always lie in the plane of the material.
- the color of the shadow image is the color of the icon. So black icons create black shadow images, green icons create green shadow images, and white icons create white shadow images.
- the movement of the shadow image as the angle of illumination moves is tied to the specific depth or motion Unison effect in a way that parallels the visual effect present in the synthetic image. Thus the movement of a shadow image as the angle of the light is altered parallels the movement that the synthetic image shows when the angle of view is altered.
- Motion shadow images move orthoparallactically as the light source is moved.
- Deep shadow images move in the same direction as the light source.
- Float shadow images move opposite to the direction of the light source.
- Levitate shadow images move in directions that are a combination of the above: Levitate Deep shadow images move in the same direction as the light in the left-right direction, but opposite from the direction of the light in the up-down direction; Levitate Float shadow images move opposite to the light in the left right direction but in the same direction as the light in the up-down direction;
- Levitate Motion shadow images show orthoparallactic motion with respect to the light movement.
- Unison Mo ⁇ h shadow images show mo ⁇ hing effects as the light source is moved. Additional unusual shadow image effects are seen when a diverging point light source, such as an LED light, is moved toward and away from a Unison film.
- the shadow images produced by Deep, SuperDeep, Float, or SuperFloat Unison synthetic images appear approximately the same size as the synthetic images.
- the shadow images of Deep and SuperDeep materials shrink because the illumination is strongly divergent, while the shadow images of Float and SuperFloat materials expand. Illuminating these materials with converging illumination causes Deep and SuperDeep shadow images to enlarge to a size greater than the synthetic images, while Float and SuperFloat shadow images shrink.
- the shadow images of Unison motion material do not change scale significantly as the convergence or divergence of illumination is changed, rather, the shadow images rotate about the center of illumination.
- Unison Levitate shadow images shrink in one direction and enlarge in the pe ⁇ endicular direction when the convergence or divergence of the illumination is changed.
- Unison Mo ⁇ h shadow images change in ways specific to the particular Mo ⁇ h pattern as the convergence or divergence of the illumination is changed. All of these shadow image effects can be used as additional authentication methods for Unison materials utilized for security, anti-counterfeiting, brand protection applications, and other similar applications.
- Figs. 3 a-i are plan views showing various embodiments and fill-factors of different patterns of symmetric two-dimensional a ⁇ ays of micro-lenses.
- Figs.3a, d and g depict micro-lenses 46, 52, and 60, respectively, that are a ⁇ anged in regular hexagonal a ⁇ ay pattern 40.
- the dashed array pattern lines 40,42, and 44 indicate the symmetry of the pattern of lenses but do not necessarily represent any physical element of the lens array.
- the lenses of Fig. 3a have substantially circular base geometry 46
- the lenses of Fig.3g have substantially hexagonal base geometries 60
- the lenses of Fig. 3d have intermediate base geometries which are rounded-off hexagons 52.
- lens geometries applies to the square a ⁇ ay 42 of lenses 48, 54, and 62, wherein these lenses have base geometries which range from substantially circular 48, to rounded-off square 54, to substantially square 62, as seen in Figs. 3b, e, and h.
- the equilateral triangular a ⁇ ay 44 holds lenses having base geometries that range from substantially circular 50, to rounded-off triangle 58, to substantially triangular 64, as seen in Figs. 3c, f and i.
- the lens patterns of Figs. 3 a-i are representative of lenses that can be used for the present system.
- the intersititial space between the lenses does not directly contribute to the synthetic magnification of the images.
- a material created using one of these lens patterns will also include an a ⁇ ay of icon elements that is a ⁇ anged in the same geometry and at approximately the same scale, allowing for differences in scale utilized to produce Unison Motion, Unison Deep, Unison Float, and Unison Levitate effects. If the interstitial space is large, such as is shown in Fig. 3c, the lenses are said to have a low fill-factor and the contrast between the image and the background will be reduced by light scattered from icon elements.
- the lenses are said to have a high fill-factor and the contrast between the image and the background will be high, providing the lenses themselves have good focal properties and icon elements are in the lenses' focal planes. It is generally easier to form high optical quality micro-lenses with a circular or nearly circular base than with a square or triangular base.
- a good balance of lens performance and minimizing of interstitial space is shown in Fig. 3d; a hexagonal array of lenses having base geometries that are rounded hexagons. Lenses having a low F# are particularly suitable for use in the present system.
- low F# we mean less than 4, and in particular for Unison Motion approximately 2 or lower.
- Low F# lenses have high curvature and a correspondingly large sag, or center thickness, as a proportion of their diameter.
- a typical Unison lens, with an F# of 0.8, has a hexagonal base 28 microns wide and a center thickness of 10.9 microns.
- polygonal base multi-zonal lenses for example hexagonal base multi-zonal lenses
- hexagonal base multi-zonal lenses significantly improve manufacturability by virtue of their stress-relieving geometry, but there are additional unexpected optical benefits obtained through the use of hexagonal base multi-zonal lenses.
- These polygonal lenses have an effective diameter that is the diameter of a circle drawn inside the corner zones around the central zone and including the side zones.
- the hexagonal base multi-zonal lens 784 of the subject disclosure performs at least as well as the spherical lens 792.
- the central zone 789 of the hexagonal base multi-zonal lens 784 provides high image resolution and shallow depth of field from a wide variety of viewing angles.
- Each of the six side zones 796 of the hexagonal base multi-zonal lens 784 of the subject invention have focal lengths that depend on the location with the zone in a complex way, but the effect is to cause the focus of the side zones 796 to be spread over a range of values 798 spanning approximately +/- 10 percent of the central zone focus, as illustrated in Figure 32.
- This vertical blurring 798 of the focal point effectively increases the depth of field of the lens in these zones 796, and provides a benefit that is equivalent to having a flat-field lens.
- the performance of the outer zones 800 of spherical lens 792 can be seen in Figure 33.
- the vertical blurring of the focal point 802 is significantly less for the spherical lens 792 than it is for the hexagonal base multi-zonal lens 784.
- a Unison material using hexagonal base multi-zonal lenses displays synthetic images that fade from focus more softly at higher viewing angles than the equivalent Unison material using spherical lenses. This is desirable because it increases the effective viewing angle of the material and therefore increases its usefulness as a security device or an image presentation device.
- the corner zones 806 of the hexagonal base multi-zonal lens 784 of Figure 32 possess diverging focal properties that provide the unexpected benefit of scattering 808 ambient illumination onto the icon plane and thereby reducing the sensitivity of the Unison material to illumination conditions.
- the spherical lens 792 of Figure 33 does not scatter the ambient illumination over as wide an area (as seen by the absence of rays scattered into the icon plane regions 804), so Unison materials made using spherical lenses have greater synthetic image brightness variations when viewed from a variety of angles than Unison materials made using hexagonal base multi-zonal lenses.
- the benefit obtained from the exemplary hexagonal base multi-zonal lenses is further magnified because hexagonal base multi-zonal lenses have a higher fill factor (ability to cover the plane) than spherical lenses.
- the interstitial space between spherical lenses provides virtually no scattering of ambient light, while this non- scattering area is much smaller in the case of hexagonal base multi-zonal lenses.
- hexagonal base multi-zonal lenses provide unexpected benefits and advantages over spherical lenses.
- Either type of lens can benefit from the addition of scattering microstructures or scattering materials introduced into, or inco ⁇ orated into, the lens interstitial spaces to enhance the scattering of ambient illumination onto the icon plane.
- the lens interstitial spaces can be filled with a material that will form a small radius meniscus, with either converging or diverging focal properties, to direct ambient illumination onto the icon plane.
- the lens interstitial zones can be originally manufactured with suitably scattering lens interstitial zones.
- a spherical lens having these proportions is very difficult to manufacture because the high contact angle between the surface of the film and the edge of the lens acts as a stress concentrator for the forces applied to separate the lens from the tool during manufacture. These high stresses tend to cause the adhesion of the lens to the film to fail and to failure of removal of the lens from the tool.
- the optical performance of a low F# spherical lens is progressively compromised for radial zones away from the center of the lens: low F# spherical lenses do not focus well except near their central zone.
- Hexagonal base lenses have an unexpected and significant benefit over lenses that have a more substantially circular base: hexagonal lenses release from their tools with lower peeling force than the optically equivalent lenses with substantially circular bases.
- Hexagonal lenses have a shape that blends from substantially axially symmetric near their center to hexagonally symmetric, with corners that act as stress concentrators, at their bases.
- the stress concentrations caused by the sha ⁇ base corners reduce the overall peeling force required to separate the lenses from their molds during manufacturing. The magnitude of this effect is substantial - the peeling forces can be reduced during manufacturing by a factor of two or more for hexagonal base lenses as compared to substantially circular base lenses.
- the image contrast of the material can be enhanced by filling the lens interstitial spaces with a light absorbing (dark colored) opaque pigmented material, effectively forming a mask for the lenses. This eliminates the contrast reduction that arises from light scattered from the icon layer through the lens interstitial spaces.
- An additional effect of this interstitial fill is that the overall image becomes darker because incoming ambient illumination is blocked from passing through the interstitial spaces to the icon plane.
- the image clarity produced by lenses having aberrant focusing at their periphery can also be improved by an opaque pigmented interstitial fill, providing that this fill occludes the abe ⁇ ant peripheral lens zone.
- a different effect can be obtained by filling the lens interstitial spaces with a white or light colored material, or a material color matched to a substrate to be used with the Unison material. If the light colored lens interstitial fill is dense enough and the icon plane inco ⁇ orates a strong contrast between the icon elements and the background, the Unison synthetic image will be substantially invisible when viewed with reflected light, yet will be distinctly visible when viewed in transmitted light from the lens side, but not visible when viewed from the icon side. This provides the novel security effect of having a one-way transmission image that is visible only in transmitted light and visible only from one side. Fluorescing materials can be utilized in a lens interstitial coating instead of, or in addition to, visible light pigments to provide additional means of authentication.
- Fig. 4 graphs the effects of changing the stereoscopic scale ratio, SSR (the icon element repeat period/ the lens array repeat period), along an axis of the present material. Zones of the system having an SSR greater than 1.0000 will produce
- zones having an SSR of substantially 1.0000 will produce Unison Motion orthoparallactic motion (OPM) effects, and zones having an SSR less than 1.0000 will produce Unison Deep and Unison SuperDeep effects. All of these effects can be produced and transitioned from one to another in a variety of ways along an axis of system film. This figure illustrates one of an infinite variety of such combinations.
- the dashed line 66 indicates the SSR value corresponding substantially to 1.0000, the dividing line between Unison Deep and Unison SuperDeep and Unison Float and Unison SuperFloat, and the SSR value which demonstrates OPM.
- zone 68 the SSR of the Unison material is 0.995, creating a Unison Deep effect.
- zone 70 Adjacent to this is zone 70 in which the SSR is ramped from 0.995 up to 1.005, producing a spatial transition from a Unison Deep to a Unison Float effect.
- the SSR in the next zone 72 is 1.005 creating a Unison Float effect.
- the next zone 74 creates a smooth transition down from a Unison Float effect to a Unison Deep effect.
- Zone 76 proceeds stepwise up from a Unison Deep effect, to OPM, to a Unison Float effect, and zone 78 steps it back down to OPM.
- the variations in repeat period needed to accomplish these effects are generally most easily implemented in the icon element layer.
- FIGs. 5 a-c are plan views depicting the effect of rotating one a ⁇ ay pattern with respect to the other in the production of material of the present system.
- Fig. 5a shows a lens array 80 having a regular periodic array spacing 82, without substantial change in the angle of the array axes.
- Fig. 5b shows an icon element a ⁇ ay 84 with a progressively changing a ⁇ ay axis orientation angle 86.
- the lens array 80 is combined with the icon element array 84 by translating the lens array over the icon a ⁇ ay, as drawn, then the approximate visual effect that results is shown in Fig. 5c.
- the material 88 created by combining lens a ⁇ ay 80 and icon a ⁇ ay 84 creates a pattern of synthetically magnified images 89, 90, 91 that vary in scale and rotation across the material.
- image 89 Towards the lower left edge of the material 88 image 89 is large and shows no rotation.
- Image 90, toward the upper middle section of material 88 is smaller and is rotated through a significant angle with respect to image 89.
- Figs. 6 a-c illustrate a method for causing one synthetically magnified OPM image 98 to mo ⁇ h into another synthetically magnified image 102 as the first image moves across a boundary 104 in the icon element patterns 92 and 94.
- Icon element pattern 92 bears circle-shaped icon elements 98, shown in the magnified inset 96.
- Icon element pattern 94 bears star-shaped icon elements 102, shown in the magnified inset 100.
- Icon element patterns 92 and 94 are not separate objects, but are joined at their boundary 104.
- Figs. 6b and X show the mo ⁇ hing effects depicted in Figs. 6b and X.
- Fig. 6b shows OPM circle images 98 moving to the right 107 across the boundary 104 and emerging from the boundary as star images 102 also moving to the right.
- Image 106 is in transition, part circle and part star, as it crosses the boundary.
- Fig. 6c of the figure shows the images after they have moved further to the right: image 98 is now closer to the boundary 104 and image 106 has almost completely crossed the boundary to complete its mo ⁇ hing from circle to star.
- the mo ⁇ hing effect can be accomplished in a less abrupt manner by creating a transition zone from one icon element pattern to the other, instead of having a hard boundary 104.
- the icons would gradually change from circle to star through a series of stages.
- the smoothness of the visual mo ⁇ hing of the resulting OPM images will depend on the number of stages used for the transition.
- the range of graphical possibilities is endless.
- the transition zone could be designed to make the circle appear to shrink while sha ⁇ star points protruded up through it, or alternatively the sides of the circle could appear to dent inward to create a stubby star that progressively became sha ⁇ er until it reached its final design.
- Figs. 7 a-c are cross-sections of materials of the present system that illustrate alternative embodiments of the icon elements.
- Fig. 7a depicts a material having lenses 1 separated from icon elements 108 by optical spacer 5.
- Icon elements 108 are formed by patterns of colorless, colored, tinted, or dyed material applied to the lower surface of optical spacer 5. Any of the multitude of common printing methods, such as inkjet, laserjet, lette ⁇ ress, flexo, gravure, and intaglio, can be used to deposit icon elements 108 of this kind so long as the print resolution is fine enough.
- Fig. 7b depicts a similar material system with a different embodiment of icon elements 112. In this embodiment the icon elements are formed from pigments, dyes, or particles embedded in a supporting material 110.
- Examples of this embodiment of icon elements 112 in supporting material 110 include: silver particles in gelatin, as a photographic emulsion, pigmented or dyed ink absorbed into an ink receptor coating, dye sublimation transfer into a dye receptor coating, and photochromic or thermochromic images in an imaging film.
- Fig. 7c depicts a microstructure approach to forming icon elements 114. This method has the benefit of almost unlimited spatial resolution.
- the icon elements 114 can be formed from the voids in the microstructure 113 or the solid regions 115, singly or in combination.
- the voids 113 can optionally be filled or coated with another material such as evaporated metal material having a different refractive index, or dyed or pigmented material.
- FIG. 8 a,b depict positive and negative embodiments of icon elements.
- Fig. 8a shows positive icon elements 116 that are colored, dyed, or pigmented 120 against a transparent background 118.
- Fig. 8b shows negative icon elements 122 that are transparent 118 against a colored, dyed, or pigmented background 120.
- a material of the present system may optionally inco ⁇ orate both positive and negative icon elements. This method of creating positive and negative icon elements is particularly well adapted to the microstructure icon elements 114 of Fig. 7c.
- Fig. 9 shows a cross-section of one embodiment of a pixel-zone material of the present system. This embodiment includes zones with lenses 124 having a short focus and other zones with lenses having a long focus 136.
- the short focus lenses 124 project images 123 of icon elements 129 in icon plane 128 disposed at the focal plane of lenses 124.
- the long focus lenses 136 project images 134 of icon elements 137 in icon plane 132 disposed at the focal plane of lenses 136.
- Optical separator 126 separates short focus lenses 124 from their associated icon plane 128.
- Long focus lenses 136 are separated from their associated icon plane 132 by the sum of the thicknesses of optical separator 126, icon plane 128, and second optical separator 130.
- Icon elements 137 in the second icon plane 132 are outside the depth of focus of short focus lenses 124 and therefore do not form distinct synthetically magnified images in the short focus lens zones.
- Fig. 10 is a cross-section of an alternate embodiment of a pixel-zone material of the present system. This embodiment includes zones with lenses 140 elevated by a lens support mesa 144 above the bases of the non-elevated lenses 148.
- the focal length of the elevated lenses 140 is the distance 158, placing the focus of these lenses in the first icon plane 152.
- the focal length of the non-elevated lenses 148 is the distance 160, placing the focus of these lenses in the second icon plane 156. These two focal lengths, 158 and 160, may be chosen to be similar or dissimilar.
- the elevated lenses 140 project images 138 of icon elements 162 in icon plane 152 disposed at the focal plane of lenses 140.
- the non-elevated lenses 148 project images 146 of icon elements 164 in icon plane 156 disposed at the focal plane of lenses 148.
- the elevated lenses 140 are separated from their associated icon elements 162 by the sum of the thickness of the lens support mesa 144 and the optical separation 150.
- the non-elevated lenses 148 are separated from their associated icon elements 164 by the sum of the thickness of the optical separation 150, the icon layer 152, and the icon separator 154.
- Icon elements 164 in the second icon plane 156 are outside the depth of focus of the elevated lenses 140 and therefore do not form distinct synthetically magnified images in the elevated lens zones.
- icon elements 152 are too close to non-elevated lenses 148 to form distinct synthetically magnified images. Accordingly, zones of material bearing elevated lenses 140 will display images 138 of the icon elements 162, while zones of material bearing non-elevated lenses 136 will display images 146 of icon elements 156.
- Figs. 11 a,b are cross-sections illustrating non-refractive embodiments of the present system.
- Fig. 11a illustrates an embodiment that utilizes a focusing reflector 166 instead of a refractive lens to project images 174 of icon elements 172.
- the icon layer 170 lies between the viewer's eyes and the focusing optics. Focusing reflectors 166 can be metallized 167 to obtain high focusing efficiency.
- the icon layer 170 is maintained at a distance equal to the focal length of the reflectors by optical separator 168.
- l ib discloses a pinhole optics embodiment of this material.
- Opaque upper layer 176 preferably black in color for contrast enhancement, is pierced by apertures 178.
- Optical separator element 180 controls the field of view of the system.
- Icon elements 184 in icon layer 182 are imaged through apertures 178 in a manner similar to the pinhole optics of a pinhole camera. Because of the small amount of light passed through the apertures, this embodiment is most effective when it is back- illuminated, with light passing through the icon plane 182 first, then through the apertures 178. Effects of each of the above-described embodiments, OPM, Deep, Float, and Levitate, can be created using either the reflective system design or the pinhole optics system design. Figs.
- FIG. 12 a,b are cross-sections comparing the structures of an all-refractive material 188 with a hybrid refractive/reflective material 199.
- Fig. 12a depicts an exemplary structure, with micro-lenses 192 separated from the icon plane 194 by optical separator 198.
- Optional sealing layer 195 contributes to the total refractive system thickness 196.
- Lenses 192 project icon images 190 toward the viewer (not shown).
- Hybrid refractive/reflective material 199 includes micro-lenses 210 with icon plane 208 directly beneath them.
- Optical spacer 200 separates the lenses 210 and the icon plane 208 from reflective layer 202.
- Reflective layer 202 can be metallized, such as by evaporated or sputtered aluminum, gold, rhodium, chromium, osmium, depleted uranium or silver, by chemically deposited silver, or by multi-layer interference films.
- Light scattered from icon layer 208 reflects from reflective layer 202, passes through icon layer 208 and into lenses 210 which project images 206 toward the viewer (not shown). Both of these figures are drawn to approximately the same scale: by visual comparison it can be seen that the total system thickness 212 of the hybrid refractive/reflective system 199 is about half the total system thickness 196 of the all-refractive system 188. Exemplary dimensions for equivalent systems are
- refractive/reflective system 199 thickness 212.
- a hybrid system having lenses 15 ⁇ in diameter can be made with a total thickness of about 8 ⁇ .
- Fig. 13 is a cross-section showing a 'peel-to-reveal ' tamper-indicating material embodiment of the present system. This embodiment does not display an image until it is tampered with.
- the untampered structure is shown in region 224, where a refractive system 214 is optically buried under a top layer 216 consisting of an optional substrate 218 and a peelable layer 220 which is conformal to the lenses 215. Peelable layer 220 effectively forms negative lens structures 220 that fit over positive lenses 215 and negate their optical power.
- Lenses 215 cannot form images of the icon layer in the untampered region, and the light scattered 222 from the icon plane is unfocused.
- Top layer 216 may include an optional film substrate 218. Tampering, shown in region 226, causes the release of top layer 216 from the refractive system 214, exposing the lenses 215 so that they can form images 228. Effects of each of the above described embodiments, OPM, Deep, Float, and Levitate, can be included in a tamper indicating 'peel-to-reveal' system of the type of Fig. 13.
- Fig. 14 is a cross-section illustrating a 'peel-to-change' tamper- indicating material embodiment of the present system.
- This embodiment displays a first image 248 of a first icon plane 242 prior to tampering 252, then displays a second image 258 at region 254 after it has been tampered with.
- the untampered structure is shown in region 252, where two refractive systems, 232 and 230, are stacked.
- the first icon plane 242 is located beneath the lenses 240 of the second system.
- Prior to tampering in region 252 the first, or upper, system 232 presents images of the first icon plane 242.
- the second icon plane 246 is too far outside the depth of focus of lenses 234 to form distinct images.
- the first lenses 234 are separated from the second lenses 240 by an optional substrate 236 and a peelable layer 238 which is conformal to the second lenses 240.
- Peelable layer 232 effectively forms negative lens structures 238 that fit over positive lenses 240 and negate their optical power.
- Top layer 232 may include optional film substrate 236. Tampering results in the peeling 256 of the top layer 232, shown in region 254, from the second refractive system 230, exposing the second lenses 240 so that they can form images 258 of the second icon layer 246. Second lenses 240 do not form images of the first icon layer 242 because the icon layer is too close to the lenses 240.
- This embodiment of a tamper indicating material is well suited to application as a tape or label applied to an article. Tampering releases the top layer 232, leaving the second system 230 attached to the article. Prior to tampering, this embodiment presents a first image 248.
- 15a depicts a two-sided material 260 that includes a single icon plane 264 that is imaged 268 by lenses 262 on one side and imaged 270 by a second set of lenses 266 on the opposite side.
- the image 268 seen from the left side (as drawn) is the minor image of the image 270 seen from the right side.
- Icon plane 264 may contain icon elements that are symbols or images which appear similar in minor image, or icon elements which appear different in minor image, or combinations of icon elements wherein a portion of the icon elements are correct-reading when viewed from one side and the other icon elements are correct-reading when viewed from the other side.
- FIG. 15b illustrates another two-sided embodiment 272 having two icon planes 276 and 278 that are imaged, 282 and 286 respectively, by two sets of lenses, 274 and 280 respectively.
- This embodiment is essentially two separate systems, 287 and 289, such as illustrated in Fig. la, that have been joined together with an icon layer spacer 277 in between them. The thickness of this icon layer spacer 277 will determine the degree that the 'wrong' icon layer is imaged 284 and 288 by a set of lenses.
- the thickness of icon layer spacer 277 is zero, such that icon layers 276 and 278 are in contact, then both icon layers will be imaged by both sets of lenses 274 and 280.
- the thickness of icon layer spacer 277 is substantially larger than the depth of focus of lenses 274 and 280, then the 'wrong' icon layers will not be imaged by the lenses 274 and 280.
- 15c shows yet another two-sided material 290 having a pigmented icon layer spacer 298 that blocks the lenses on one side of the material from seeing the 'wrong' set of icons.
- Lenses 292 image 294 icon layer 296 but cannot image icon layer 300 because of the presence of pigmented icon layer 298.
- lenses 302 image 304 icon layer 300 but cannot image icon layer 296 because of the presence of pigmented icon layer 298. Effects of each of the above described embodiments, OPM, Deep, Float, and Levitate, can be displayed from either side of a two-sided material according to this embodiment, and the projected images 294 and 304 can be of the same or different colors.
- 15d discloses a further two-sided material 306 embodiment having lenses 308 that image 318 icon layer 314 and lenses 316 on the opposite side that image 322 icon layer 310.
- Icon layer 310 is close to, or substantially in contact with, the bases of lenses 308 and icon layer 314 is close to, or substantially in contact with, the bases of lenses 316.
- Icons 310 are too close to lenses 308 to form an image, so their light scatters 320 instead of focusing.
- Icons 314 are too close to lenses 316 to form an image, so their light scatters 324 instead of focusing.
- Figs. 16 a-f are cross-sections and co ⁇ esponding plan views illustrating three different methods for creating grayscale or tonal icon element patterns and subsequent synthetically magnified images with the present system.
- Figs. 16 a-c are cross-section details of the icon side of a material 307, including part of optical separator 309 and a transparent micro structured icon layer 311.
- the icon elements are formed as bas- relief surfaces 313, 315, 317 that are then filled with a pigmented or dyed material 323, 325, 327 respectively.
- the underside of the icon layer may be optionally sealed by a sealing layer 321 that can be transparent, tinted, colored, dyed, or pigmented, or opaque.
- the bas-relief micro structures of icon elements 313, 315, and 317 provide thickness variations in the dyed or pigmented fill material, 323, 325, and 327 respectively, that create variations in the optical density of the icon element as seen in plan view.
- the plan views corresponding to icon elements 323, 325, and 327 are plan views 337, 339, and 341.
- Fig. 16 a includes icon element 313, dyed or pigmented icon element fill 323, and co ⁇ esponding plan view 337.
- the cross section view of the icon plane at the top of this figure can only show one cutting plane through the icon elements.
- the location of the cutting plane is indicated by the dashed line 319 through the plane views 337, 339, and 341. Accordingly, the cross-section of icon element 313 is one plane through a substantially hemispherical-shaped icon element.
- Fig. 16 b includes icon element 315, dyed or pigmented icon element fill 325, and co ⁇ esponding plan view 339.
- Plan view 339 shows that the icon element 315 is a bas-relief representation of a face.
- the tonal variations in an image of a face are complex, as shown by the complex thickness variations 325 in the cross-section view.
- an array of icon elements of this type can be synthetically magnified within the present material system to produce images that show equivalent grayscale variations representing, in this example, the image of a face.
- Fig. 16 c includes icon element 317, dyed or pigmented fill 327, and co ⁇ esponding plan view 341.
- the bas-relief shape of this icon element structure produces a tonal variation in the appearance of the dyed and pigmented fill 327 and in the synthetically magnified image produced by the present material system.
- Icon element 317 illustrates a method for creating a bright center in a rounded surface, as compared to the effect of icon element 313 which creates a dark center in a rounded surface.
- Figs. 16 d,e disclose another embodiment 326 of transparent bas-relief micro structured icon layer 311 including icon elements 329 and 331 that are coated with a high refractive index material 328.
- the icon layer 311 can be sealed with an optional sealing layer 321 that fills the icon elements 329 and 331, 330 and 332, respectively.
- the high refractive index layer 328 enhances the visibility of sloping surfaces by creating reflections from them by total internal reflection.
- Plan views 342 and 344 present representative images of the appearance of icon elements 329 and 331 and their synthetically magnified images.
- This high refractive index coating embodiment provides a kind of edge-enhancement effect without adding pigment or dye to make the icons and their images visible.
- Fig. 16 f discloses yet another embodiment 333 of transparent bas-relief micro structured icon 335 utilizing an air, gas, or liquid volume 336 to provide visual definition for this phase interface 334 microstructure.
- Optional sealing layer 340 may be added with or without optional adhesive 338 to entrap the air, gas, or liquid volume 336.
- the visual effect of a phase interface icon element is similar to that of a high refractive index coated icon element 329 and 331.
- FIG. 17 a-d are cross-sections showing the use of the present system as a laminating film in conjunction with printed information, such as may be utilized in the manufacture of I.D. cards and driver's licenses, wherein the material 348 (consisting of the coordinated micro-a ⁇ ay of lenses and images described above) covers a substantial proportion of the surface.
- Fig. 17a depicts an embodiment of Unison used as a laminate over print 347.
- Material 348 having at least some optical transparency in the icon layer is laminated to fibrous substrate 354, such as paper or paper substitute, with lamination adhesive 350, covering or partly covering print element 352 that had previously been applied to the fibrous substrate 354.
- Fig. 17b shows an embodiment of the system material used as a laminate over a print element 352 applied to a nonfibrous substrate 358, such as a polymer film.
- a nonfibrous substrate 358 such as a polymer film.
- material 348 having at least some optical transparency in the icon layer is laminated to nonfibrous substrate 358, such as polymer, metal, glass, or ceramic substitute, with lamination adhesive 350, covering or partly covering print element 352 that had previously been applied to the nonfibrous substrate 354.
- Fig. 17c depicts the use of a print element directly on the lens side of material 360.
- material 348 has print element 352 directly applied to the upper lens surface.
- the print element 352 lies on top of the material and the dynamic image effects can be seen around the print element.
- the material 348 is used as the substrate for the final product, such as cu ⁇ ency, ID cards, and other articles requiring authentication or providing authentication to another article.
- Fig. 17d depicts the use of a print element directly on the icon side of an at- least partially transparent material 362.
- Print element 352 is applied directly to the icon layer or sealing layer of an at-least partially transparent system material 348. Because the system material 348 is at least partially transparent, the print element 352 can be seen through it and the effect of this combination is to provide the dynamic image effect in combination with the static print.
- the system material 348 is used as the substrate for the final product, such as cu ⁇ ency, ID cards, and other articles requiring authentication or providing authentication to another article.
- a system material 348 can be both ove ⁇ rinted (Fig. 17c) and backside printed (Fig. 17d), then optionally laminated over print on a substrate (Figs. 17 a,b).
- Figs. 18 a-f are cross-sections illustrating the application of the present system to, or inco ⁇ oration into, various substrates and in combination with printed information.
- the embodiments of Figs. 18 a-f differ from those of Figs. 17 a-d in that the former figures disclose system material 348 that covers most or all of an article, whereas the present figures disclose embodiments wherein the system material or its optical effect do not substantially cover a whole surface, but rather cover only a portion of a surface.
- Fig. 18 a-f are cross-sections illustrating the application of the present system to, or inco ⁇ oration into, various substrates and in combination with printed information.
- the embodiments of Figs. 18 a-f differ from those of Figs. 17 a-d in that the former figures disclose system material 348 that covers most or all of an article, whereas the present figures disclose embodiments wherein the system material or its optical effect do not substantially cover a whole surface, but rather cover only a portion of a surface
- FIG. 18a depicts a piece of at-least partially transparent system material 364 adhered to a fibrous or non-fibrous substrate 368 with adhesive element 366.
- Optional print element 370 has been directly applied to the upper, lens, surface of material 364.
- Print element 370 may be part of a larger pattern that extends beyond the piece of material 364.
- the piece of material 364 is optionally laminated over print element 372 that was applied to the fibrous or non- fibrous substrate prior to the application of the material 364.
- Fig. 18b illustrates an embodiment of single-sided system material 364 inco ⁇ orated into an non-optical substrate 378 as a window, wherein at least some of the edges of the system material 364 are captured, covered, or enclosed by the non- optical substrate 378.
- Print elements 380 may be optionally applied on top of the system material lens surface and these print elements may be aligned with, or co ⁇ espond to, print elements 382 applied to the non-optical substrate 378 in the area adjacent to print element 380.
- print elements 384 can applied to the opposite side of the non-optical substrate aligned with, or co ⁇ esponding to, print elements 386 applied to the icon or sealing layer 388 of the system material 364.
- the effect of a window of this kind will be to present distinct images when the material is viewed from the lens side and no images when viewed from the icon side, providing a one-way image effect.
- Fig. 18c shows a similar embodiment to that of Fig.
- a material window of this kind will be to present different distinct images when the material is viewed from opposite sides.
- a window inco ⁇ orated into a cu ⁇ ency paper could display the numerical denomination of the bill, such as "10" when viewed from the face side of the bill, but when viewed from the back side of the bill the Unison window could display different information, such as "USA", that may be in the same color as the first image or a different color.
- FIG. 18d illustrates a transparent substrate 373 acting as the optical spacer for a material formed by a zone of lenses 374 of limited extent and an icon layer 376 extending substantially beyond the periphery of the zone of lenses 374.
- the present effects will only be visible in that zone that includes both lenses and icons (corresponding to lens zone 374 in this figure).
- Both the lenses 374 and the adjacent substrate may optionally be printed 375, and print elements may also be applied to the icon layer 376 or to an optional sealing layer covering the icons (not indicated in this figure - see Fig. 1).
- Fig. 18e shows an embodiment that is similar to that of Fig. 18d, except that the icon plane 402 does not extend substantially beyond the extent of the lens zone 400.
- Optical spacer 398 separates the lenses 400 from the icons 402.
- Print elements 404 and 406 correspond to print elements 375 and 377 in Fig. 18d.
- Multiple zones 400 can be used on an article after the manner of this embodiment; each zone can have separate effects.
- Fig. 18f depicts an embodiment that is similar to Fig. 18d except that the present embodiment inco ⁇ orates optical spacer 408 that separates lenses 413 from icon plane 410. Lenses 413 extend substantially beyond the periphery of the icon zone 412. Print elements 414 and 416 correspond to print elements 375 and 377 in Fig. 18d. Multiple lens zones can be used on an article after the manner of this embodiment; wherever a lens zone is placed the present effects will be seen; the size, rotation, stereoscopic depth position, and OPM properties of the images can be different for each lens zone.
- This embodiment is well suited for application to ID cards, credit cards, drivers' licenses, and similar applications.
- Figs. 19 a,b illustrate cross-sectional views comparing the in- focus field of view of a spherical lens with that of a flat field aspheric lens when each are inco ⁇ orated into a structure of the type described above.
- Fig. 19a illustrates a substantially spherical lens as applied in a system as described above.
- Substantially spherical lens 418 is separated from icon plane 422 by optical spacer 420.
- Image 424 projected out pe ⁇ endicular to the surface of the material originates at focal point 426 within the icon layer 422.
- the image 424 is in sha ⁇ focus because the focal point 426 is within the icon layer 422.
- image 428 is blu ⁇ y and out of focus because the co ⁇ esponding focal point 430 is no longer in the icon plane, but is above it a substantial distance.
- Arrow 432 shows the field curvature of this lens, equivalent to the sweep of the focal point from 426 to 430.
- the focal point is within the icon plane throughout the zone 434, then moves outside of the icon plane in zone 436.
- Lenses which are well suited to application in coordination with a plane of printed images or icons typically have a low F#, typically less than 1, resulting in a very shallow depth of focus - higher F# lenses can be used effectively with Deep and Float effects, but cause proportionate vertical binocular disparity with effects described herein when used with Unison Motion effects.
- the field curvature of a substantially spherical lens limits the field of view of the image: the image is distinct only within the in- focus zone 434, rapidly going out of focus for more oblique viewing angles.
- Substantially spherical lenses are not flat-field lenses, and the field curvature of these lenses is amplified for low F# lenses.
- Fig. 19b illustrates an aspheric lens as applied to the present system. As an aspheric lens, its curvature is not approximated by a sphere. Aspheric lens 438 is separated from icon layer 442 by optical spacer 440. Aspheric lens 438 projects image 444 of icon plane 442 normal to the plane of the material . The image originates at focal point 446. The focal length of aspheric lens 438 lies within the icon plane 442 for a wide range of viewing angles, from normal 444 to oblique 448, because it has a flat-field 452.
- the focal length of the lens varies according to the angle of view through it.
- the focal length is shortest for normal viewing 444 and increases as the viewing angle becomes more oblique.
- the focal point 450 is still within the thickness of the icon plane, and the oblique image is therefore still in focus for this oblique viewing angle 448.
- the in-focus zone 454 is much larger for the aspheric lens 438 than the in-focus zone 434 of the substantially spherical lens 418.
- the aspheric lens 438 thus provides an enlarged field of view over the width of the associated image icon so that the peripheral edges of the associated image icon do not drop out of view compared to that of the spherical lens
- FIGs. 20 a-c are cross-sections illustrating two benefits of utility which result from the use of a thick icon layer. These benefits apply whether the lens 456 used to view them is substantially spherical 418 or aspheric 438, but the benefits are greatest in combination with aspheric lenses 438.
- Fig. 20a illustrates a thin icon layer 460 system material including lenses 456 separated from icon layer 460 by optical spacer 458.
- Icon elements 462 are thin 461 in comparison to the field curvature of the lens 463, limiting the in-focus zone to a small angle, the angle between the image projected in the normal direction 464 and the highest oblique angle image 468 that has a focal point 470 within the icon layer 460.
- the greatest field of view is obtained by designing the normal image focus 466 to lie at the bottom of the icon plane, thereby maximizing the oblique field of view angle, limited by the point at which the focal point 470 lies at the top of the icon plane.
- the field of view of the system in Fig. 20a is limited to 30 degrees. Fig.
- FIG. 20b illustrates the benefits obtained from the inco ⁇ oration of an icon plane 471 that is thick 472 in comparison to the field curvature of lens 456.
- Lenses 456 are separated from thick icon elements 474 by optical spacer 458.
- Thick icon elements 474 remain in focus 475 over a larger field of view, 55 degrees, than the thin icon elements 462 of Fig. 20a.
- the normal image 476 projected through lenses 456 from focal point 478 is in clear focus, and the focus remains clear while the angle of view increases all the way up to 55 degrees, where oblique image 480 focal point 482 lies at the top of the thick icon plane 471.
- the increased field if view is greatest for a flat-field lens, such as the aspheric lens 438 of Fig. 19b.
- Fig. 20c illustrates yet another advantage of a thick icon plane 492; reducing the sensitivity of the present system material to variations in thickness S that may result from manufacturing variations.
- Lens 484 is spaced a distance S from the bottom surface of icon layer of thickness i.
- Lens 484 projects image 496 from focal point 498 disposed at the bottom of icon layer 492.
- This figure is drawn to demonstrate that variations in the optical space S between the lenses and the icon layer can vary over a range equal to the thickness of the icon layer i without loss of image 496, 500, 504 focus.
- the optical spacer thickness is about (S + i / 2) and the focal point 502 of image 500 is still within the thickness i of icon layer 492.
- the thickness of the optical spacer has increased to (S + i ) 490 and the focal point 506 of image 504 lies at the top of thick icon element 494.
- the optical spacer thickness can therefore vary over a range conesponding to the thickness of the icon layer i : a thin icon layer therefore provides a small tolerance for optical spacer thickness variations and a thick icon layer provides a larger tolerance for optical spacer thickness variations.
- An additional benefit is provided by a thick icon layer 492.
- Imperfect lenses, such as substantially spherical lenses may have a shorter focal length 493 towards their edges than at their center 496. This is one aspect of the common spherical abenation defect of substantially spherical lenses.
- FIG. 21 is a plan view that shows the application of the present system to cunency and other security documents as a 'windowed' security thread.
- Fig. 21 shows a windowed thread structure including system material 508 that has been slit into a ribbon, refe ⁇ ed to as a "thread", that is typically in the range of 0.5 mm to 10 mm in width. Thread 508 is inco ⁇ orated into the fibrous document substrate 510 and provides windowed zones 514.
- the thread 508 may optionally inco ⁇ orate a pigmented, dyed, filled, or coated sealing layer 516 to increase image contrast and/or to provide additional security and authentication features, such as electrical conductivity, magnetic properties, nuclear magnetic resonance detection and authentication, or to hide the material from view in reflected illumination when viewed from the back side of the substrate (the side opposite the side presenting the Unison synthetic images and an adhesive layer 517 to strengthen the bond between the thread 508 and the fibrous substrate 510.
- the thread 508 is maintained in an orientation to keep the lenses uppermost so that the image effects are visible in the windowed zones 514.
- Both the fibrous substrate 510 and the thread may be ove ⁇ rinted by print elements 518 and the fibrous substrate may be printed 520 on its opposite face.
- Thread 508 and its image effects 522 are only visible from the upper surface 521 of the substrate 510 in the windowed zones 514.
- Thread 508 is covered by fibrous substrate material at the inside zones 512 and the image effects 522 are not substantially visible in these zones.
- OPM effects are particularly dramatic when inco ⁇ orated into thread 508. (See Fig. 22)
- the fibrous substrate 510 is tilted in various directions the OPM image can be made to scan across the width 524 of the thread, producing a startling and dramatic visual effect. This scanning feature of an OPM image makes it possible to present image 522 which is larger than the width of the thread 508.
- the user examining the document containing a windowed thread 508 can then tilt the document to scan the whole image across the thread, scrolling it like a marquee sign.
- the effects of the Deep, Float, and Levitate embodiments can also be used to advantage in a windowed thread format.
- the thread 508 may be at least partially inco ⁇ orated in security papers during manufacture by techniques commonly employed in the paper-making industry. For example, thread 508 may be pressed within wet papers while the fibers are unconsolidated and pliable, as taught by U.S. Patent 4,534,398 which is inco ⁇ orated herein by reference.
- the windowed thread of the present system is particularly well suited for application to cunency. A typical total thickness for the thread material is in the
- thread 508 comprises: (a) one or more optical spacers; (b) one or more optionally periodic planar anays of micro-images or icons positioned within, on, or next to an optical spacer; and (c) one or more optionally periodic planar anays of non-cylindrical micro lenses positioned on or next to either an optical spacer or a planar icon anay, with each micro-lens having a base diameter of less than 50 microns.
- the micro-images or icons constitute filled voids or recesses that are formed on a surface of the one or more optical spacers, while the non-cylindrical micro-lenses are aspheric micro-lenses, with each aspheric micro-lens having a base diameter ranging from about 15 to about 35 microns.
- At least one pigmented sealing or obscuring layer 516 may be positioned on the planar anay(s) of micro-images or icons for increasing contrast and thus visual acuity of the icons and also for masking the presence of thread 508 when the thread is at least partially embedded in a security document.
- thread 508 comprises: (a) an optical spacer having opposing upper and lower planar surfaces; (b) a periodic a ⁇ ay of micro-images or icons comprising filled recesses formed on the lower planar surface of the optical spacer; (c) a periodic anay of non-cylindrical, flat field, aspheric or polygonal base multi-zonal micro-lenses positioned on the upper planar surface of the optical spacer, wherein each micro-lens have a base diameter ranging from about 20 to about 30 microns; and (d) a pigmented sealing or obscuring layer 516 positioned on the icon anay.
- the optical spacer(s) may be formed using one or more essentially colorless polymers including, but not limited to, polyester, polypropylene, polyethylene, polyethylene terephthalate, polyvinylidene chloride, and the like.
- the optical spacer(s) is formed using polyester or polyethylene terephthalate and has a thickness ranging from about 8 to about 25 microns.
- the icon and micro-lens anays can be formed using substantially transparent or clear radiation curable material including, but not limited to acrylics, polyesters, epoxies, urethanes and the like.
- the anays are formed using acrylated urethane which is available from Lord Chemicals under the product designation U107.
- the icon recesses formed on the lower planar surface of the optical spacer each measures from about 0.5 to about 8 microns in depth and typically 30 microns in micro-image or icon width.
- the recesses can be filled with any suitable material such as pigmented resins, inks, dyes, metals, or magnetic materials.
- the recesses are filled with a pigmented resin comprising a sub-micron pigment which is available from Sun Chemical Co ⁇ oration under the product designation Spectra Pac.
- the pigmented sealing or obscuring layer 516 can be formed using one or more of a variety of opacifying coatings or inks including, but not limited to, pigmented coatings comprising a pigment, such as titanium dioxide, dispersed within a binder or carrier of curable polymeric material.
- the sealing or obscuring layer 516 is formed using radiation curable polymers and has a thickness ranging from about 0.5 to about 3 microns.
- Thread 508 which is described above, may be prepared in accordance with the following method: (a) applying a substantially transparent or clear radiation curable resin to the upper and lower surfaces of the optical spacer; (b) forming a micro-lens anay on the upper surface and an icon anay in the form of recesses on the lower surface of the optical spacer; (c) curing the substantially transparent or clear resin using a source of radiation; (d) filling the icon anay recesses with a pigmented resin or ink; (e) removing excess resin or ink from the lower surface of the optical spacer; and (f) applying a pigmented sealing or obscuring coating or layer to the lower surface of the optical spacer.
- ⁇ -speed non-contact sensors such as capacitance sensors, magnetic field sensors, optical transmission and opacity sensors, fluorescence, and/or nuclear magnetic resonance.
- Inco ⁇ oration of fluorescent materials into the lens, substrate, icon matrix, or icon fill elements of a Unison film can enable covert or forensic authentication of the Unison material by observation of the presence and spectral characteristics of the fluorescence.
- a fluorescing Unison film can be designed to have its fluorescent properties visible from both sides of the material or from only one side of the material.
- a Unison material inco ⁇ orating an optical isolation layer beneath the icon plane may be designed to exhibit fluorescence in a number of different ways: fluorescent color A visible from the lens side, no fluorescence visible from the optical isolation layer side, fluorescent color A or B visible from the optical isolation layer side but not from the lens side, and fluorescent color A visible from the lens side and fluorescent color A or B visible from the optical isolation layer side.
- fluorescent color A visible from the lens side no fluorescence visible from the optical isolation layer side
- fluorescent color A visible from the lens side and fluorescent color A or B visible from the optical isolation layer side The uniqueness provided by the variety of fluorescent signatures possible can be used to further enhance the security of the Unison material.
- the optical isolation layer can be a layer of pigmented or dyed material, a layer of metal, or a combination of pigmented layers and metal layers, that absorbs or reflects the fluorescent emission from one side of the material and prevents it from being seen from the other side.
- Icons formed from shaped voids and their inverse, icons formed from shaped posts, are particularly enabling for adding machine-readable authentication features to a Unison material security thread for cunency and other high value documents.
- the icon matrix, the icon fill, and any number of back coats (sealing coats) can all, separately and/or in all combinations, inco ⁇ orate non-fluorescing pigments, non- fluorescing dyes, fluorescing pigments, fluorescing dyes, metal particles, magnetic particles, nuclear magnetic resonance signature materials, lasing particles, organic LED materials, optically variable materials, evaporated metal, thin film interference materials, liquid crystal polymers, optical upconversion and downconversion materials, dichroic materials, optically active materials (possessing optical rotary power), optically polarizing materials, and other allied materials.
- a dark or colored coating such as a magnetic material or conductive layer
- a color of the icon plane is objectionable when seen through the back side of a substrate
- Other types of cu ⁇ ency security threads commonly inco ⁇ orate a metal layer, typically aluminum, to reflect light that filters through the surface substrate, thereby providing similar brightness to the sunounding substrate.
- Aluminum or other color neutral reflecting metal can be used in similar manner to mask the appearance of a Unison thread from the back side of a paper substrate by applying the metal layer on the back surface of the Unison material and then optionally sealing it in place.
- a pigmented layer can be utilized for the same pu ⁇ ose, that of hiding or obscuring the visibility of the security thread from the "back" side of the document, in place of a metallized layer, or in conjunction with it.
- the pigmented layer can be of any color, including white, but the most effective color is one that matches the color and intensity of the light internally scattered within, and outside of, the fibrous substrate.
- a metallized layer to a Unison material can be accomplished in a number of ways, including direct metallization of the icon or sealing layer of the Unison material by evaporation, sputtering, chemical deposition, or other suitable means, or lamination of the icon or sealing layer of the Unison material to the metallized surface of a second polymer film.
- Synthetic images can be designed as binary patterns, having one color (or absence of color) defining the icons and a different color (or absence of color) defining the background; in this case each icon zone includes a complete single-tone image that utilizes image 'pixels' that are either full on or full off. More sophisticated synthetic images can be produced by providing tonal variations of the selected icon color.
- the synthetic image tonal variation can be created by controlling the density of the color in each icon image or by effectively 'half-toning' the synthetic image by including or excluding design elements in selected groups of icons.
- the first method, controlling the density of the color in each icon image may be accomplished by controlling the optical density of the material creating the microprinted icon image. One convenient method to do this utilizes the filled void icon embodiment, already described previously.
- the second method 'half-toning' the synthetic image by including or excluding design elements in selected groups of icons, illustrated in Figure 23, accomplished by including image design elements in a proportion of icon zones that is equal to the color density desired.
- Figure 23 illustrates this with an example using a hexagonal repeat pattern for the icon zones 570 that would be coordinated with a similar hexagonal repeat pattern of lenses.
- Each of the icon zones 570 do not contain identical information. All of the icon image elements, 572, 574, 576, and 578 are present at substantially the same color density. Icon image elements 572 and 574 are present in some of the icon zones and different icon image elements are present in other icon zones. Some icon zones contain the single icon image element 570.
- the icon image element 572 is present in half of the icon zones, icon image element 574 is present in three- fourths of the icon zones, icon image element 578 is present in half of the icon zones, and icon image element 576 is present in one- third of the icon zones.
- the information present in each icon zone determines whether its associated lens will show the color of the icon image pattern or the color of the icon image background from a particular viewing orientation. Either image elements572 or 578 will be visible in all of the lenses associated with this icon pattern, but the synthetic image 580 space of icon image element 572 overlaps the synthetic image space of icon image element 578. This means that the overlap zone 582 of the synthetic images of icons 572 and 578 will appear at 100% color density, because every lens will project icon image color in this zone.
- an icon image may have minimum features on the order of two microns in dimension, but those features may be placed accurately on any point on a grid of 0.25 micron spacing.
- the smallest feature of the icon image is eight times larger than the placement accuracy of that feature.
- this method is illustrated using a hexagonal icon pattern 594, but it applies equally well to any other usable pattern symmetry.
- this method relies on the use of different information in at least one icon zone.
- two different icon patterns, 596 and 598 are each present in half of the icon zones (for clarity only one of each pattern is shown in this figure).
- These icon images produce a composite synthetic image 600 that inco ⁇ orates synthetic image 602 created by icon image elements 596, and synthetic image 604, created by icon image elements 598.
- the two synthetic images, 602 and 604, are designed to have overlapped areas, 606 and 608, that appear to have 100% color density while the non-overlapped areas 605 have 50% color density.
- the minimum dimension of the overlapped areas in the composite synthetic image may be as small as the synthetic magnification-scaled positioning accuracy of the icon image elements, and therefore may be smaller than the minimum feature size of the two constituent synthetic images that are designed to overlap in a small region.
- the overlap regions are used to create the characters for the number "10" with nanower lines than would otherwise be possible.
- This method can also be used to create nanow patterns of gaps between icon image elements, as shown in Figure 24b.
- Hexagonal icon zones 609 could be square or any other suitable shape to make a space-filling anay, but hexagonal is prefened.
- half the icon patterns the icon image 610, and half of them are the icon image 611.
- these two patterns would be relatively uniformly distributed among the icon zones. All of the elements of these patterns are depicted as being of substantially equal and uniform color density. In isolation these two patterns do not clearly suggest the form of the final image, and this can be used as a security element - the image is not obvious until it is formed by the overlying lens a ⁇ ay.
- One instance of the synthetic image 612 formed by the combination of the synthetic image of icon elements 610 with the synthetic image of icon elements 611 is shown, whereby the gaps that remain between the separate synthetic images form the numeral "10".
- two synthetic images are combined to form the final synthetic image, so the colored parts of this image 613 show 50% color density.
- This method is not limited by the details of this example: three icons could have been used instead of two, the gaps defining the desired element in the composite synthetic images can have variable widths and unlimited shape variety, and this method can be combined with either the methods of Figures 23, 24a,b or 25, or an other icon image design method we have taught. Covert, hidden information can be inco ⁇ orated into the icon images that cannot be seen in the resulting synthetic images.
- FIG. 25 Two methods for accomplishing this are illustrated by Figure 25.
- the first method is illustrated by the use of matched icon images 616 and 618.
- Icon image 616 shows a solid border pattern and the number "42" contained inside of the border.
- Icon image 618 shows a solid shape with the number "42" as a graphical hole in that shape.
- the perimeter shapes of icon images 616 and 618 are substantially identical and their relative position within their respective icon zones, 634 and 636, are also substantially identical.
- the border of the composite synthetic image 622 will show 100% color density because all icon images have a pattern in that conesponding area, so there is full overlap in the synthetic images created from icon images 616 and 618.
- the color density of the interior 624 of the composite synthetic image 620 will be 50%, since the image of the space sunounding the "42" comes from icon images 618 that only fill half the icon zones, and the image of the colored "42" comes from icon images 616 that also fill half the icon zones. Consequently, there is no tonal differentiation between the "42" and its background, so the observed composite synthetic image 626 will show an image having a 100% color density border 628 and a 50% color density interior 630.
- triangles 632 A second method for inco ⁇ orating covert information into icon images is illustrated by triangles 632 in Figure 25.
- Triangles 632 may be randomly placed within the icon zones (not shown in this figure) or they can be placed in an anay or other pattern that does not substantially match the period of the icon zones 634, 632.
- Synthetic images are created from a multiplicity of regularly anayed icon images that are imaged by a conesponding regular anay of micro-lenses. Patterns in the icon plane that do not substantially co ⁇ espond to the period of the micro-lens a ⁇ ay will not form complete synthetic images.
- the pattern of triangles 632 therefore will not create a coherent synthetic image and will not be visible in the observed synthetic image 626.
- This method is not limited to simple geometric designs, such as triangles 632: other covert information, such as alpha-numeric information, bar codes, data bits, and large-scale patterns can be inco ⁇ orated into the icon plane with this method.
- Figure 26 illustrates a general approach to creating fully three dimensional integral images in a Unison material (Unison 3-D).
- a single icon zone 640 contains icon image 642 that represents a scale-distorted view of an object to be displayed in 3- D as seen from the vantage point of that icon zone 640.
- the icon image 642 is designed to form a synthetic image 670 of a hollow cube 674.
- Icon image 642 has a foreground frame 644 that represents the nearest side 674 of hollow cube 672, tapered gap patterns 646 that represent the comers 676 of the hollow cube 672, and a background frame 648 that represents the farthest side 678 of the hollow cube 672.
- icon image 642 does not conespond to the proportions of the nearest side 674 and the farthest side 678 of the synthetic image hollow cube 672.
- the reason for the difference in scale is that images that are to appear further from the plane of the Unison material experience greater magnification, so their size in the icon image must be reduced in order to provide the conect scale upon magnification to form the synthetic image 672.
- icon zone 650 that includes a different icon image 652.
- icon image 652 represents a scale-distorted view of the synthetic image 672 as seen from the different vantage point of this icon zone 650.
- Icon zone 660 is located a further distance away on the Unison 3-D material and it presents yet another scale-distorted icon image 662, including icon image 662 with foreground frame 664, tapered gap patterns 667, and background frame 668.
- icon image 652 represents a transitional stage between icon images 642 and 662.
- each icon image in a Unison 3-D material may be unique, but each will represent a transitional stage between the icon images to either side of it.
- Synthetic image 670 is formed from a multiplicity of icon images like icon images 640, 650, and 660 as synthetically imaged through an associated lens anay.
- the synthetic image of the hollow cube 674 shows the effects of the different synthetic magnification factors that result from the effective repeat periods of the different elements of each of the icon images. Let us assume that the hollow cube image 674 is intended to be viewed as a SuperDeep image.
- icon zone 640 was disposed some distance to the lower left of icon zone 650, and icon zone 660 was disposed some distance to the upper right of icon zone 650, it can be seen that the effective period of the foreground frames 644, 654, and 664 will be less than that of the background frames 648, 658, and 668, thereby causing the closest face 676 of the cube (conesponding to the foreground frames 644, 654, and 664) to lie closer to the plane of the Unison material and the farthest face 678 of the cube to lie deeper and further from the plane of the Unison material, and to be magnified by a greater factor.
- the comer elements 646, 656, and 667 coordinate with both the foreground and background elements to create the effect of smoothly changing depth between them.
- the method of designing icon images for Unison 3-D is more fully described in Figure 27.
- This figure isolates the method for a single image projector 680.
- a single image projector includes a lens, an optical spacer, and an icon image; the icon image having substantially the same dimensions as the repeat period of the lens (allowing for the small differences in scale that create the Unison visual effects).
- the field of view for the lens and its associated icon is shown as the cone 682: this also conesponds to an inversion of the focal cone of the lens, so the proportions of the field of view cone 682 are determined by the F# of the lens.
- this cone shows this cone as having a circular base, the base shape will actually be the same as the shape of an icon zone, such as a hexagon.
- an icon zone such as a hexagon.
- the diameter of the image planes 684, 688, and 692 expands with the field of view cone: in other words, as the depth of image increases, area covered by the field of view cone increases.
- the field of view at the shallowest depth plane 684 only encompasses portions of "NIS” of the word UNISON, while the middle depth plane 688 encompasses all of “NIS” and portions of “U” and “O” and the deepest depth plane 692 encompasses almost all of "UNISON", lacking only part of the final "N”.
- the information they presented (UNISONs 686, 690, and 694) by each of these synthetic image planes 684, 688, and 692, must ultimately be inco ⁇ orated into a single icon image in image projector 680. This is accomplished by capturing the information in the field of view cone 686 at each depth plane 684, 688, and 692, then scaling the resulting icon image patterns to the same dimensions.
- Icon image 696 represents the field of view of UNISON image 686 as seen at depth plane 684
- icon image 704 represents the field of view of UNISON image 690 as seen at depth plane 688
- icon image 716 represents the field of view of UNISON image 694 as seen at depth plane 692.
- icon image elements 698 originate from a portion of the first "N" of UNISON image 686
- icon image element 700 originates from a portion of the "I” of UNISON image 686
- icon image elements 702 originate from portions of the "S" of UNISON image 686.
- icon image element 706 originates from a portion of the "U” of UNISON image 690
- icon image element 708 originates from the first "N” of UNISON image 690
- icon image element 710 originates from the "S” of UNISON image 690
- icon image element 714 originates from a portion of the "O” of UNISON image 690.
- synthetic images 686, 690, and 694 are presented at similar scale
- icon image 704 for the middle depth plane 688 presents its UNISON letters at a smaller scale than those of icon image 696. This accounts for the higher synthetic magnification that icon image 704 will experience (when synthetically combined with a multiplicity of sunounding icon images for the same depth plane).
- icon image 716 inco ⁇ orates icon image elements 718 that originate from the UNISON image 694 and the UNISON letters inco ⁇ orated in its icon image are at a further reduced scale.
- the final icon image for this image projector is created by combining these three icon images 696, 704, and 716 into a single icon image 730, shown in Figure 28.
- the combined icon elements 732 inco ⁇ orate all of the graphical and depth information necessary for the image projector 680 to make its contribution to the synthetic image formed from a multiplicity of image projectors, each inco ⁇ orating the specific icon image information that results from the intersection of its own field of view cone, centered on the image projector, with the levels and elements of the synthetic image to be produced.
- each image projector Since each image projector is displaced by at least one lens repeat period from every other image projector, each image projector will cany different information resulting from the intersection of its field of view cone with the synthetic image space.
- Each of the icon images required to present a chosen 3-D image can be computed from knowledge of the three-dimensional digital model of the synthetic image, desired depth position and depth span to be presented in the synthetic image, the lens repeat period, the lens field of view, and the ultimate graphical resolution of the icon images. This latter factor puts an upper limit on the level of detail that can be presented at each depth plane. Since depth planes that lie further from the plane of the Unison material cany a larger amount of information (because of the increased field of view) the graphical resolution limit of the icons has the greatest impact on the resolution of these synthetic image depth planes.
- Figure 29 illustrates how the method of Figure 27 can be applied to a complex three-dimensional synthetic image, such as an image of the priceless ice-age carved mammoth ivory artifact, the Lady of Brassempouy 742.
- Individual image projector 738 inco ⁇ orating at least a lens, an optical spacing element, and an icon image (not shown in this figure), lies in the plane 740 of a Unison material that separate the float synthetic image space from the deep synthetic image space.
- the synthetic image space spans the Unison material such that a portion of the image lies in the float synthetic image space and a portion lies in the deep synthetic image space.
- the image projector 738 has a substantially conical field of view that extends both into the deep synthetic image space 744 and into the float synthetic image space 746.
- a chosen number of deep image planes are selected, 748 and 752-762, at whatever spacing is required to obtain the deep synthetic image space resolution desired.
- a chosen number of float image planes are selected, 750 and 764-774, at whatever spacing is required to obtain the float synthetic image space resolution desired.
- the number of image planes shown in Figure 29 is limited to a small number but the actual number of image planes selected may be high, such as 50 or 100 planes, or more, to obtain the desired synthetic image depth resolution.
- the method of Figures 27 and 28 is then applied to obtain the icon image at each depth plane by determining the shape of the intersection of the surface of the object 742 with the selected depth plane 756-774.
- the resulting separate icon images are scaled to the final size of the combined icon image. All of the float icon images are first rotated 180 degrees (because they undergo that rotation again when they are projected, thereby returning them to their conect orientation in the synthetic image) then they are combined with the deep icon images to form the final icon image for this image projector 738.
- the resolution of the synthetic image depends on the resolution of the optical projectors and the graphical resolution of the icon images. We have obtained icon image graphical resolutions, less than 0.1 micron, that exceed the theoretical optical resolution limit of magnifying optics ( 0.2 micron). A typical icon image is created with a resolution of 0.25 micron.
- Unison materials can be manufactured by sheet or web processing utilizing tools that separately inco ⁇ orate the lens and icon microstructures. Both the lens tools and the icon tools are originated using photomasks and photoresist methods. Lens tools are initially designed as semiconductor-type masks, typically black chrome on glass.
- Masks having sufficient resolution can be created by photoreduction, electron beam writing, or laser writing.
- a typical mask for a lens tool will inco ⁇ orate a repeating pattern of opaque hexagons at a chosen period such as 30 microns, with clear lines separating the hexagons that are less than 2 microns wide.
- This mask is then used to expose photoresist on a glass plate using a conventional semiconductor UV exposure system.
- the thickness of the resist is selected to obtain the desired sag of the lens. For example, a thickness of 5 microns of AZ 4620 positive photoresist is coated onto a glass plate by suitable means, such as by spin coating, dip coating, meniscus coating, or spraying, to form lenses having a nominal 30 micron repeat and a nominal 35 micron focal length.
- the photoresist is exposed with the mask pattern, and developed down to the glass in a conventional manner, then dried and degassed at 100 C for 30 minutes.
- the lenses are formed by thermal reflow according to standard methods that are known in the art.
- the resulting photoresist micro-lenses are coated with a conductive metal, such as gold or silver, and a negative nickel tool is created by electroforming. Icon tools are created in a similar manner.
- An icon pattern is typically designed with the aid of CAD software and this design is transmitted to a semiconductor mask manufacturer. This mask is used in similar manner to the lens mask, except the thickness of the resist to be exposed is typically in the range of 0.5 micron to 8 microns, depending on the optical density of the desired synthetic image.
- the photoresist is exposed with the mask pattern, developed down to glass in a conventional manner, coated with a conductive metal, and a negative nickel tool is created by electroforming.
- the icons can be created in the form of voids in the resist pattern or they can be created in the form of "mesas" or posts in the resist pattern, or both.
- Unison materials can be manufactured from a variety of materials and a
- An exemplary method of manufacture is to form the icons as voids in a radiation cured liquid polymer that is cast against a base film, such as 75 gage adhesion-promoted PET film, then to form the lenses from radiation cured polymer on the opposite face of the base film in conect alignment or skew with respect to the icons, then to fill the icon voids with a submicron particle pigmented coloring material by gravure-like doctor blading against the film surface, solidify the fill by suitable means (ex: solvent removal, radiation curing, or chemical reaction), and finally apply an optional sealing layer that may be either clear, dyed, pigmented, or inco ⁇ orate covert security materials.
- the manufacture of Unison Motion material requires that the icon tool and the lens tool inco ⁇ orate a chosen degree of misalignment of the axes of symmetry of the two anays.
- This misalignment of the icon and lens patterns axes of symmetry controls the synthetic image size and synthetic image rotation in the produced material. It is often desirable to provide the synthetic images substantially aligned with either the web direction or the cross-web direction, and in these cases the total angular misalignment of the icons and the lenses is divided equally between the lens pattern and the icon pattern.
- the degree of angular misalignment required is usually quite small.
- a total angular misalignment on the order of 0.3 degree is suitable to magnify 30 micron icon images to a size of 5.7 mm in a Unison Motion material.
- the total angular misalignment is divided equally between the two tools, so each tool is skewed through an angle of 0.15 degree in the same direction for both tools.
- the skew is in the same direction because the tools form microstructures on opposite faces of a base film, so the skews of the tools add to each other, instead of canceling each other. Skew can be inco ⁇ orated into the tools at the time of the original design of the masks by rotating the whole pattern through the desired angle before writing it.
- Skew can also be mechanically inco ⁇ orated into a flat nickel tool by cutting it at the appropriate angle with a numerically controlled mill.
- the skewed tool is then formed into a cylindrical tool using the skew-cut edge to align the tool to the rotational axis of an impression cylinder.
- the synthetic magnification micro-optic system herein can be combined with additional features including but not limited to these embodiments as single elements or in various combinations, such as icon fill materials, back coatings, top coatings, both patterned and non-pattemed, fill or inclusions in the lens, optical spacer or icon materials, as a laminate or coating, inks and or adhesives including aqueous, solvent or radiation curable, optically transparent, translucent or opaque, pigmented or dyed Indicia in the form of positive or negative material, coatings, or print including but not limited to inks, metals, fluorescent, or magnetic materials, X-ray, infrared, or ultraviolet absorbent or emitting materials, metals both magnetic and non-magnetic including aluminum, nickel, chrome, silver, and gold; magnetic coatings and particles for detection or information storage; fluorescent dye and pigments as coatings and particles; IR fluorescent coatings, fill, dyes or particles; UV fluorescent coatings, fill, dyes or particles; phosphorescent dye and pigments as coatings and particles, planchettes, DNA
- the synthetic magnification micro-optic system herein has many fields of use and applications. Examples include: Government and defense applications - whether Federal, State or Foreign (such as Passports, ID Cards, Driver's Licenses, Visas, birth Certificates, Vital Records, Voter Registration Cards, Voting Ballots, Social Security Cards, Bonds, Food Stamps, Postage Stamps, and Tax Stamps); cunency - whether Federal, State or Foreign (such as security threads in paper cunency, features in polymer cunency, and features on paper cunency); documents (such as Titles, Deeds, Licenses, Diplomas, and Certificates); financial and negotiable instruments (such as Certified Bank Checks,
- Suitable materials for the embodiments described above include a wide range of polymers. Acrylics, acrylated polyesters, acrylated urethanes, polypropylenes, £ ox t ⁇ i urethanes, and polyesters have suitable optical and mechanical properties for both the microlenses and the microstructured icon elements.
- Suitable materials for the optional substrate film include most of the commercially available polymer films, including acrylic, cellophane, Saran, nylon, polycarbonate, polyester, polypropylene, polyethylene, and polyvinyl.
- Microstructured icon fill materials can include any of the materials listed above as suitable for making microstructured icon elements, as well as solvent based inks and other commonly available pigment or dye vehicles.
- Optional sealing layer materials can include any of the materials listed above as suitable for making microstructured icon elements, plus many different commercially available paints, inks, overcoats, varnishes, laquers, and clear coats used in the printing and paper and film converting industries. There is no prefened combination of materials - the choice of materials depends o the details of the material geometry, on the optical properties of the system, and on the optical effect that is desired.
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- Physics & Mathematics (AREA)
- General Physics & Mathematics (AREA)
- Optics & Photonics (AREA)
- Manufacturing & Machinery (AREA)
- Engineering & Computer Science (AREA)
- Business, Economics & Management (AREA)
- Finance (AREA)
- Accounting & Taxation (AREA)
- Chemical & Material Sciences (AREA)
- General Health & Medical Sciences (AREA)
- Electromagnetism (AREA)
- Health & Medical Sciences (AREA)
- Crystallography & Structural Chemistry (AREA)
- Toxicology (AREA)
- Credit Cards Or The Like (AREA)
- Lenses (AREA)
- Stereoscopic And Panoramic Photography (AREA)
- Devices For Indicating Variable Information By Combining Individual Elements (AREA)
- Paper (AREA)
- Laminated Bodies (AREA)
- Thermal Transfer Or Thermal Recording In General (AREA)
- Holo Graphy (AREA)
- Optical Elements Other Than Lenses (AREA)
- Burglar Alarm Systems (AREA)
- Telescopes (AREA)
Abstract
Description
Claims
Priority Applications (30)
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MXPA06005763A MXPA06005763A (en) | 2003-11-21 | 2004-11-22 | Micro-optic security and image presentation system. |
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DK04811944.0T DK1695121T3 (en) | 2003-11-21 | 2004-11-22 | Microoptic security and image presentation system |
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DE202004021714U DE202004021714U1 (en) | 2003-11-21 | 2004-11-22 | Micro-optical security and image presentation system |
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EP11002546.7A EP2397883B1 (en) | 2003-11-21 | 2004-11-22 | Micro-optic security and image presentation system |
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EP11008302.9A EP2460667B1 (en) | 2003-11-21 | 2004-11-22 | Micro-optic security and image presentation system |
EP10014985.5A EP2284018B1 (en) | 2003-11-21 | 2004-11-22 | Micro-optic security and image presentation system |
JP2006541650A JP4918364B2 (en) | 2003-11-21 | 2004-11-22 | Micro optical security and image display system |
RU2010142167/28A RU2602397C2 (en) | 2003-11-21 | 2004-11-22 | Micro-optical safety and image display system |
KR1020117003576A KR101225311B1 (en) | 2003-11-21 | 2004-11-22 | Micro-optic security and image presentation system |
ES04811944.0T ES2504890T3 (en) | 2003-11-21 | 2004-11-22 | Image presentation system and micro-optical security |
TW094118028A TW200643469A (en) | 2004-11-22 | 2005-06-01 | Micro-optic security and image presentation system |
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