Patent Application
20230264504
The present subject matter relates generally to the field of security, and more specifically to the use of planchettes as security features in documents and other printed products.
One of the most common and effective strategies for making paper products difficult to replicate is using security fibers. Security fibers are materials that are added during the paper manufacturing process. Fibers are a cost-effective security method that has been used for decades. Because they can be embedded into the paper document, they are virtually impossible to remove without damaging the paper itself. The distribution of the fibers is also visibly random in the paper.
Fiber can also be added to plastics, coatings, nonwovens, and other applications. The fibers can add another level of anti-counterfeiting technology. These fibers can be seen as a decorative feature to the unsuspecting eye, but they can expose fake products under examination.
There are several kinds of security fibers, all of which behave differently in printed products to bolster the fraud protection strategy. Light-sensitive fibers can be designed to fluoresce under different wavelengths of light. UV-reactive fibers are the most common. They light up underneath UV light. Fibers can also be designed to be visible or invisible in daylight. As such, fibers can be invisible and only fluoresce when exposed to UV light. Temperature-sensitive fibers can change colors when hot or cold temperatures are applied to the area. One common example of heat-sensitive fibers is a fingerprint-sensitive area of a check, where the paper darkens from white to red after one uses a fingertip to press or create friction (and therefore heat) against the paper. Both types of material can be visible or invisible fibers that can only be detected by light or heat. Other examples may involve color changes from opaque to clear. Document security applications include not only thermochromic but also photochromic and metameric. As with thermochromic, it is generally understood that photochromic and metameric are associated with inks, but similar effects could be associated with security fibers or planchettes.
Security fibers can be integrated into a variety of paper or mixed-material documents. Common and well-known examples include government products such as banknotes and passports, but security fibers are also found in checks, anti-counterfeiting labels, packaging, plastics, lottery tickets, stamps, and nonwovens. During the manufacturing process, security fibers can be a certain diameter and/or cross-sectional shape and can be cut to any desired length and embedded and dispersed into the material. While most fibers are rayon, nylon, or cotton, other materials may be used.
Prior work on security fiber optimization explored security fiber characteristics and combinations of diverse security fiber types together in one substrate.
Planchettes are cellulose-based tiny disks or round elements of, for example, about 1.6 mm in size. They are similar to security fibers in many respects, except for their shape and size. Planchettes can be optimized as distinct security substrates separate from the paper of the host document. Besides being easier to see, planchettes can be carriers for security fibers, and their surfaces are large enough to accept printed images. This provides options for customizing planchettes through graphic design strategies typically associated with static printed artwork. Planchettes may be visible in daylight to the naked eye, fluorescent, phosphorescent under UV light, thermochromic, or reactive. They may be visible in one color and can be combined with an invisible fluorescent color that is revealed under UV such as a 365 nm UV lamp. Most planchettes seem intended for reflected or UV light inspection, though they can be hard to inspect in reflected or UV light when embedded inside of (and concealed by) the document substrate. Accordingly, designing planchettes for transmitted light inspection may both overcome this limitation and facilitate new security roles for planchettes.
A security system for an article of manufacture may comprise: a first set of planchettes configured to luminesce when a first frequency of light is cast on the first planchettes; and a second set of planchettes configured to luminesce when a second frequency of light is cast on the first planchettes. A camera or a sensor may detect whether the planchettes are reflecting back a specific color or pattern. A computer may be programmed to use data from the camera or sensor to decide whether the article of manufacture is genuine or counterfeit.
In accordance with another aspect, a method of detecting whether an article of manufacture is authentic or genuine comprising: performing chemical ionization mass spectrometry on an article of manufacture; detecting whether a certain frequency of light is detected by a chemic mass spectrometer; if the certain frequency of light is detected, determining that the article of manufacture contains a planchette; determining the article of manufacture is genuine if the article of manufacture is determined to contain a planchette.
A method of scanning a planchette may comprise steps such as: illuminating the planchette with a specific frequency of light (or range of frequencies of light); capturing an image of the planchette with a camera; and storing the image or a hash of the image of the planchette. In some methods, there is no camera or sensor used. Light may be cast or shone onto the planchette to illuminate or reveal parts of the planchette not normally visible with reflected light (e.g., room-base lighting).
A method of manufacturing an article of manufacture (such as a security card) may comprise: attaching a first set of planchettes to the security card wherein the first set of planchettes reflect a specific pattern when they are illuminated with a light source at a specific frequency; attaching a second set of planchettes to the security card wherein the second set of planchettes reflect a different pattern at the same frequency; determining the article of manufacture is a counterfeit unless the first and second sets of planchettes are visible. The planchettes may be manufactured such that they must be illuminated at a specific angle (e.g., coaxially) in order for the pattern to be visible or luminesce.
Another example might be: a method of manufacturing an article of manufacture (such as a $100 dollar bill) may comprise: incorporating a first set of planchettes in the dollar bill (the banknote substrate) wherein the first set of planchettes reflect a specific color when they are illuminated with a light source at a specific frequency; incorporating a second set of planchettes in the dollar bill wherein the second set of planchettes reflect a different color at the same frequency; determining the article of manufacture is a counterfeit unless both sets of planchettes are visible. The method may involve a human looking at the dollar bill to determine whether the planchettes are visible. Alternatively, a camera or a sensor may detect whether the planchettes are reflecting back a specific color or pattern. A computer may be programmed to use data from the camera or sensor to decide whether the article of manufacture is genuine or counterfeit.
A security system for an article of manufacture may comprise: a first set of planchettes configured to luminesce when a first frequency of light is cast on the first planchettes; and a second set of planchettes configured to luminesce when a second frequency of light is cast on the first planchettes. The first frequency may be different from the second frequency. The first and second set may comprise one planchette or a plurality of planchettes. The first set of planchettes may be configured so that they only luminesce when light of a first specific frequency is cast on the planchettes. The second set of planchettes may be configured so that they only luminesce when light a second specific frequency is cast on the planchettes.
In accordance with an aspect of the present invention, a security system for an article of manufacture comprises: one or more first planchettes included in the article of manufacture and configured to luminesce when a first frequency of light is directed to the one or more first planchettes; and one or more second planchettes included in the article of manufacture and configured to luminesce when a second frequency of light is directed to the one or more second planchettes. The one or more first planchettes and the one or more second planchettes having at least one of the following characteristics: (i) the first frequency is different from the second frequency, the one or more first planchettes are configured not to luminesce when the second frequency of light is directed to the one or more first planchettes, and the one or more second planchettes are configured not to luminesce when the first frequency of light is directed to the one or more second planchettes; (ii) the one or more first planchettes are configured to luminesce at a first color when the first frequency of light is directed to the one or more first planchettes, and the one or more second planchettes are configured to luminesce at a second color different from the first color when the second frequency of light is directed to the one or more second planchettes; or (iii) the one or more first planchettes are configured to reflect a first pattern when the first frequency of light is directed to the one or more first planchettes, and the one or more second planchettes are configured to reflect a second pattern when the second frequency of light is directed to the one or more second planchettes.
In some embodiments, the first frequency of light is same as the second frequency of light under the characteristic (ii). The first frequency of light is same as the second frequency of light under the characteristic (iii). The one or more first planchettes are configured to reflect the first pattern when the first frequency of light is directed to the one or more first planchettes at a first angle, and the one or more second planchettes are configured to reflect the second pattern when the second frequency of light is directed to the one or more second planchettes at a second angle, under the characteristic (iii). At least one of the first frequency of light or the second frequency of light may be a UV light frequency.
In specific embodiments, the one or more first planchettes are configured to luminesce when the first frequency of light is directed to the one or more first planchettes at a first angle. The one or more second planchettes are configured to luminesce when the second frequency of light is directed to the one or more second planchettes at a second angle.
In some embodiments, the first and second planchettes comprise at least one of (i) a plurality of first planchettes embedded at different depths of the article of manufacture exhibiting different levels of visibility when the first frequency of light is directed to the first planchettes; or (ii) a plurality of second planchettes embedded at different depths of the article of manufacture exhibiting different levels of visibility when the frequency of light is directed to the second planchettes.
In specific embodiments, the first and second planchettes comprise at least one of (i) one or more first planchettes composed of a first iridescent material; or (ii) one or more second planchettes composed of a second iridescent material.
In some embodiments, the first and second planchettes comprise at least one of (i) one or more first planchette substrates including at least one of first pigments incorporated therein, first surface printing thereon, or first security fibers incorporated therein; or (ii) one or more second planchette substrates including at least one of second pigments incorporated therein, second surface printing thereon, or second security fibers incorporated therein.
In specific embodiments, the first and second planchettes comprise at least one of (i) one or more first planchette substrates including first security fibers incorporated therein, the one or more first planchette substrates and the first security fibers having different UV responses; or (ii) one or more second planchette substrates including second security fibers incorporated therein, the one or more second planchette substrates and the second security fibers having different UV responses.
In some embodiments, the first and second planchettes comprise at least one of (i) one or more first planchette substrates including first security fibers incorporated therein, the first security fibers containing a first UV-reactive microprinting; or (ii) one or more second planchette substrates including second security fibers incorporated therein, the second security fibers containing a second UV-reactive microprinting. If a security fiber is tiny compared to the size of a planchette, then printed text applied to the edge of a fiber (not the planchette surface) might be so small as to be described as nanoprinting.
In specific embodiments, the first and second planchettes comprise at least one of (i) one or more first planchette substrates each including a first planchette surface having a first UV-reactive microprinting thereon; or (ii) one or more second planchette substrates each including a second planchette surface having a second UV-reactive microprinting thereon.
In some embodiments, the first and second planchettes comprise at least one of (i) a plurality of first planchette substrates including a plurality of first planchette surfaces on which a first UV-reactive microprinting is placed, placement of the microprinting being different for each of the plurality of first planchette substrates in relation to a first planchette edge of each first planchette surface of the plurality of first planchette surfaces; or (ii) a plurality of second planchette substrates including a plurality of second planchette surfaces on which a second UV-reactive microprinting is placed, placement of the microprinting being different for each of the plurality of second planchette substrates in relation to a second planchette edge of each second planchette surface of the plurality of second planchette surfaces.
In specific embodiments, the first and second planchettes comprise at least one of (i) one or more first planchette substrates each having printed work on a first planchette surface oriented to be invisible in reflected light and be visible in transmitted light; or (ii) one or more second planchette substrates each having printed work on a second planchette surface oriented to be invisible in reflected light and be visible in transmitted light.
In some embodiments, the first and second planchettes comprise at least one of (i) one or more first planchette substrates each having printed work on a first planchette surface oriented to be invisible in reflected light and be visible in transmitted light, the one or more first planchette substrates being same in color as the article of manufacture; or (ii) one or more second planchette substrates each having printed work on a second planchette surface oriented to be invisible in reflected light and be visible in transmitted light, the one or more second planchette substrates being same in color as the article of manufacture.
In accordance with another aspect, a method of detecting whether an article of manufacture is genuine comprises: directing a first frequency of light to the article of manufacture; directing a second frequency of light to the article of manufacture; detecting whether one or more first planchettes in the article of manufacture luminesce at the first frequency of light and whether one or more second planchettes in the article of manufacture luminesce at the second frequency of light having at least one of three characteristics: (i) the first frequency is different from the second frequency, the one or more first planchettes are configured not to luminesce when the second frequency of light is directed to the one or more first planchettes, and the one or more second planchettes are configured not to luminesce when the first frequency of light is directed to the one or more second planchettes; (ii) the one or more first planchettes are configured to luminesce at a first color when the first frequency of light is directed to the one or more first planchettes, and the one or more second planchettes are configured to luminesce at a second color different from the first color when the second frequency of light is directed to the one or more second planchettes; or (iii) the one or more first planchettes are configured to reflect a first pattern when the first frequency of light is directed to the one or more first planchettes, and the one or more second planchettes are configured to reflect a second pattern when the second frequency of light is directed to the one or more second planchettes; and determining that the article of manufacture is genuine if the one or more first planchettes and the one or more second planchettes are detected in the article of manufacture having at least one of the three characteristics.
In accordance with another aspect of the invention, a system of detecting whether an article of manufacture is genuine comprises: a light source to direct light to the article of manufacture at a first frequency and at a second frequency; an image detector including non-transitory computer readable instructions stored on a tangible computer read storage medium, the instructions causing a microprocessor connected to the image detector to: detect whether one or more first planchettes in the article of manufacture luminesce at the first frequency of light and whether one or more second planchettes in the article of manufacture luminesce at the second frequency of light having at least one of three characteristics: (i) the first frequency is different from the second frequency, the one or more first planchettes are configured not to luminesce when the second frequency of light is directed to the one or more first planchettes, and the one or more second planchettes are configured not to luminesce when the first frequency of light is directed to the one or more second planchettes; (ii) the one or more first planchettes are configured to luminesce at a first color when the first frequency of light is directed to the one or more first planchettes, and the one or more second planchettes are configured to luminesce at a second color different from the first color when the second frequency of light is directed to the one or more second planchettes; or (iii) the one or more first planchettes are configured to reflect a first pattern when the first frequency of light is directed to the one or more first planchettes, and the one or more second planchettes are configured to reflect a second pattern when the second frequency of light is directed to the one or more second planchettes; and determine that the article of manufacture is genuine if the one or more first planchettes and the one or more second planchettes are detected in the article of manufacture having at least one of the three characteristics.
Other features and aspects will become apparent from the following detailed description, which taken in conjunction with the accompanying drawings illustrate, by way of example, the features in accordance with embodiments of the claimed subject matter. This summary is not intended to identify key or essential features of the claimed subject matter, nor is it intended to limit the scope of the claimed subject matter, which is defined solely by the claims attached hereto.
The patent or application file contains at least one drawing executed in color. Copies of this patent or patent application publication with color drawing(s) will be provided by the Office upon request and payment of the necessary fee.
One or more example embodiments of the subject matter are described in detail with reference to the following drawings. These drawings are provided to facilitate understanding of the present subject matter and should not be read as limiting the breadth, scope, or applicability thereof. For purposes of clarity and ease of illustration, these drawings are not necessarily made to scale.
These drawings are not intended to be exhaustive or to limit the subject matter to the precise form(s) disclosed. It should be understood that the present subject matter can be practiced with modification and alteration, and that the subject matter is limited only by the claims and the equivalents thereof.
As a security feature, planchettes can be hard to inspect in reflected or UV light when embedded inside of (and concealed by) the document substrate. The present disclosure explores designing planchettes for transmitted light inspection which may both overcome this limitation and facilitate new security roles for planchettes.
While the shape of a security fiber might be described as straight, curved, or wavy, planchettes have an edge contour that depends on how they are punched. Typical planchette shapes include round, hexagonal, and rectangular, as shown
Planchettes may or may not respond to UV, and for those that do the UV response may or may not be the same as the visible light color. As seen in
Another important characteristic of planchettes is color, which can mean different things: the color of a planchette substrate in visible and/or ultraviolet (UV) light, the visible and/or UV color(s) of security fibers embedded in a planchette substrate, or the visible and/or UV color(s) of printed images on a planchette surface. Paper planchettes with various visible, invisible, UV bright, and UV dull color responses are shown in
Planchette “color” might also include specific infrared (IR) characteristics. This approach might apply in circumstances where visible planchettes could interfere with machine readability (in manufacturing quality control systems, passport readers, banknote processing equipment, etc.) but invisible planchettes with reflected or transmitted IR characteristics might not. Further, IR imaging might simply produce better captures than visible or UV light imaging for planchettes embedded inside the document substrate, where the planchette surfaces are concealed.
Composition and Security Fibers
Paper planchette substrates can also incorporate security fibers, but with significantly different design conventions and goals as compared to security fibers added directly to a security document substrate. First, security fiber density is typically low throughout macro security substrates, but fiber density in a planchette substrate must be very high to ensure that every planchette contains a cluster of fibers when punched. Second, planchettes containing multiple fibers together can be easier for document users to locate than a single isolated security fiber due to their larger size and better visibility. Third, because the fibers are clustered, each planchette becomes a training tool that helps document users identify how many different fiber types are present in the planchette. In contrast, in typical security document substrates, users may have to search to locate even a single security fiber; when one is found, users still do not know whether other kinds of security fibers are also present throughout the substrate. Fourth, monochromatic security fibers added directly to security document substrates are randomly placed and unregistered. However, security fibers within an individual planchette are collectively bounded by, and therefore registered to, the planchette edge, other fibers, and the tint color of the planchette substrate. This disclosure omits a complete discussion of why this internal registration of several disparate color components is important, but generally, it can help a planchette resist certain methods of simulation.
Examples of planchettes containing security fibers are shown in visible light in
Printed Artwork
Compared to thin security fibers, the large size and flat shape of planchettes allow them to accept visible and/or UV-reactive printed images. For example, the planchette in
Finally, the microprinting placement on each fiber/planchette is unique in relation to the planchette edge even as the general microprinting pattern is recognizable between planchettes, as shown in
However, much like the invisible planchette in
Planchettes punched from tinted substrates such as those in
Multicolor microprinting design was described in prior work. See, e.g., U.S. patent application Ser. No. 17/961,951, filed Oct. 7, 2022, entitled MICROPRINTING TECHNIQUES FOR PRINTING SECURITY SYMBOLS ON A SUBSTRATE, which is incorporated herein by reference in its entirety. It is extendable to planchette microprinting art, though planchette art embedded inside the document substrate can be hard to see. Accordingly, in planchette contexts, artwork concepts should not necessarily be limited to microprinting because bolder multicolor designs with less fine detail might be easier to inspect.
In
The mockup in
A final but important distinction between offset artwork design for full documents as opposed to planchettes is how repeating and nonrepeating artwork is used. Artwork, including simultaneous offset artwork, should be nonrepeating in macro document designs to prevent step-and-repeat counterfeiting. In contrast, repeating artwork may be desirable in substrates from which planchettes will be punched because it ensures each planchette captures a tiny piece of the same artwork pattern regardless of the location from which it is punched in the macro design. Because the placement of the artwork relative to the planchette edges varies, each specific planchette features its own unique artwork placement, making the artwork nonrepeating across a population of planchettes even if the source artwork is repeating. If fully nonrepeating artwork were included in a planchette substrate, the artwork patterns on two different planchettes might look significantly different from one another and could confuse users. Possibly, a compromise between repeating and nonrepeating art could also be used for planchette artwork design where artwork variation is more subtle than in macro document designs.
Designing for Transmitted Light
As discussed in prior examples, a problem in planchette design is that planchettes may be located at any depth within the document substrate. In reflected light, the document substrate may conceal the color of a planchette substrate or the details of any visible printing or special visual effects on the planchette surface. The document substrate may also prevent incident UV from reaching planchette components such as UV-reactive security fibers or UV-reactive artwork or may mask the visible fluorescence of these components.
For example,
Even non-tinted planchette substrates containing visible artwork may be hard to locate or inspect in reflected light if the visible artwork is on the reverse of the planchette, as shown in
The planchettes in
Prior work has discussed simultaneous offset, which is the ability of certain security offset printing presses to apply images in register on opposite sides of a substrate. See, e.g., U.S. patent application Ser. No. 17/962,053, filed Oct. 7, 2022, entitled OFFSET PRINTING OF SECURITY SYMBOLS ON A SUBSTRATE, which is incorporated herein by reference in its entirety. Some concepts from the simultaneous offset series could be adapted to planchette design, including the use of opaque white inks as shown in
Just as
Planchettes can be embedded into an article of manufacture to help prevent counterfeiting or unauthorized copying of that medium or object. An article of manufacture may include a medium or an object. A medium can be an item such as a document, a license, a passport, paper currency, a baseball card, etc. Planchettes can also be embedded into an object. Objects can include items such as dolls, furniture, jewelry, household goods, computer parts, or other physical, tangible items.
Methods of embedding the planchette into the medium may include printing, attaching, installing, forming in, or inserting. The medium or object may be generated, created, manufactured, assembled, or made with the planchette during manufacture, or the planchette may be added, attached, embedded, etc. after the article of manufacture was created.
Planchettes may be generated in different shapes such as ovals, circles, rectangles, triangles, hexagons, and other shapes. Planchettes may have a length and width greater than the depth. For example, a “disc-shaped” planchette may be circular and the depth may be smaller than the diameter (e.g., a flat shape).
A medium may have sufficient value such that a third party would want to make a counterfeit or unauthorized copy of the medium. The value may be realized directly such as a $20 bill. Alternatively, the medium may have value by providing access to a location or because it serves as a form of identification. Mediums such as a security badge, passport, or driver's license may provide both identification and access.
Embedding a planchette or plurality of planchettes into a medium or object may be part of a security system to prevent counterfeiting or unauthorized copying of the medium or object. In some cases, multiple planchettes may be embedded into the medium or object. The planchettes may be dispersed in a unique pattern or orientation or placed in an unusual location. For example, a grid of 50 locations may be selected for embedding the planchettes. A plurality of planchettes can be added to the grid (e.g., at least 5 but less than 45 planchettes). The plurality of planchettes can form a symbol, wherein the presence and absence of planchettes form the symbol. In some configurations, identical planchettes may be used to form the symbol, or the symbol may be composed of different color planchettes or planchettes with different patterns (stripes, dotes, dashes, etc.). The plurality of different patterns may compose the symbol or merely the presence or absence of a planchette in a particular location on the medium or object. The symbol composed on the planchettes may be an identifier or unique identifier (e.g., a serial number or code). The symbol may be associated with a specific medium or object, a date or location in which the medium or objected was manufactured, and/or a company producing or purchasing the medium or object.
As previously mentioned, embedding the planchette into the medium or object may be a part of a larger security system to prevent counterfeiting or unauthorized copying. For example, planchettes may be used with security fibers, specialty ink, and/or microprinting to make copying or counterfeiting more difficult
Planchettes may be made by various processes. A planchette may be punched or cut from a substrate. The substrate may be printed with a pattern, stripes, lettering, waves, etc. The substrate may contain printing on one, two, three, or more sides. Planchettes may also be formed individually using techniques such as mold-based casting.
Planchettes in a set of planchettes may be generated such that they have the same pattern on each planchette in the set. Alternatively, the patten may be offset on each planchette so that the patterns are variations of each other.
Planchettes may include a plurality of materials. For example, a planchette may be composed of plastic and contain a metal alloy or rare earth metal. Planchettes may be generated that utilize magnetic ink or they may include a magnetic metal.
Various methods of reading or scanning the planchette may be used. For example, SEM (Scanning Electron Microscope) analysis, EEG (Electroencephalography) analysis, TEM (Transmission Electron Microscopy), or other instrumental analysis may be used to read or view the planchette. Planchettes can be detected using technology such as chemical ionization mass spectrometry or ICPMS (Inductively Coupled Plasma Mass Spectrometry). For example, a method of detecting whether an article of manufacture is authentic or genuine comprising: performing chemical ionization mass spectrometry on an article of manufacture; detecting whether a certain frequency of light is detected by a chemic mass spectrometer; if the certain frequency of light is detected, determining that the article of manufacture contains a planchette; determining the article of manufacture is genuine if the article of manufacture is determined to contain a planchette.
A method of scanning a planchette may comprise steps such as: illuminating the planchette with a specific frequency of light (or range of frequencies of light); capturing an image of the planchette with a camera; and storing the image or a hash of the image of the planchette. In some methods, there is no camera or sensor used. Light may be cast or shone onto the planchette to illuminate or reveal parts of the planchette not normally visible with reflected light (e.g., room-base lighting).
Planchettes may be visible to a camera or the naked eye (unassisted human vision) under indirect white light. One or more parts of the planchettes may become illuminated when light of specific frequency is cast on the planchettes. A planchette may be difficult to distinguish (e.g., to see) from the article of manufacture without a specific frequency of light shining on the article of manufacture. A planchette may be difficult to distinguish (e.g., to see) from the article of manufacture without a specific frequency of light shining on the article of manufacture at a specific angle (e.g., oblique lighting, coaxial lighting/retroreflective, or direct lighting). A planchette may be characterized as being invisible if it cannot easily be distinguished from the article of manufacture to which it is attached.
In some configurations, a planchette may comprise an identifier. The identifier may be unique to the planchette, or it may be unique to a set of planchettes. For example, planchettes could contain an identifier to indicate the date of manufacture or the customer purchasing the planchette. The identifier could be a stock keeping unit, a universal product code, a serial number, or alphanumeric code. The identifier may be readable by a human looking at the planchette using reflected or room light. In some configurations, the identifier on the planchette may be specifically designed so that it is not readable by a human without magnification (e.g., a light microscope, magnifying glass, or electronic scanning microscope may be needed to see the identifier). The identifier may be encoded (e.g., a QR Code or barcode) so that it is not directly readable by a human. The planchette and/or the identifier may be configured to be readable only when light at a specific frequency (e.g., 365 nanometers, 800 nanometers, etc.) illuminates the planchette. The planchette may be configured to become visible only when light of specific type (such as coaxial light) or direction (e.g., oblique, transmitted, etc.) is cast onto the planchette.
The identifier of the planchette may be a seed value for determining how to read a second identifier on the planchette. For example, if light of a specific frequency is cast or illuminated onto a planchette, the planchette may display a code. A sensor may be configured to read the code and send the code to a computer. A computer may receive the code, apply a code function to the code to generate a result. The result may be a second frequency of light needed to illuminate another part of the planchette. The code function may be a secret.
The planchette may be configured such that a part of the planchette is visible to a camera or a human when the planchette is illuminated with a first frequency of light or range of frequencies (e.g., white light). The planchette may be configured such that a second part of the planchette becomes visible when a second frequency of light (or second range of frequencies) shines on the planchette. Adding the second frequency of light (or second range of frequencies) may cause the planchette to visibly change shape, because a new portion of the planchette becomes visible when the second frequency of light (or ranges of light) is cast onto the planchette.
In some configurations, the planchettes may comprise circuitry such as RFID or magnetic tags.
The presence or absence of a planchette or a specific type of planchette can be used to determine whether an article of manufacture is genuine or counterfeit. For example: a method of manufacturing an article of manufacture (such as a security card) may comprise: incorporating a first set of planchettes in the security card wherein the first set of planchettes reflect a specific pattern when they are illuminated with a light source at a specific frequency; incorporating a second set of planchettes in the security card wherein the second set of planchettes reflect a different pattern at the same frequency; determining the article of manufacture is a counterfeit if the first and second sets of planchettes is visible. The planchettes may be manufactured such that they must be illuminated at a specific angle (e.g., coaxially) in order for the pattern to be visible or luminesce.
Another example might be: a method of manufacturing an article of manufacture (such as a $100 dollar bill) may comprise: incorporating a first set of planchettes in the dollar bill wherein the first set of planchettes reflect a specific color when they are illuminated with a light source at a specific frequency; incorporating a second set of planchettes in the dollar bill wherein the second set of planchettes reflect a different color at the same frequency; determining the article of manufacture is a counterfeit unless both sets of planchettes are visible. The method may involve a human looking at the dollar bill to determine whether the planchettes are visible. Alternatively, a camera or a sensor may detect whether the planchettes are reflecting back a specific color or pattern. A computer may be programmed to use data from the camera or sensor to decide whether the article of manufacture is genuine or counterfeit.
A security system for an article of manufacture may comprise: a first set of planchettes configured to luminesce when a first frequency of light is cast on the first planchettes; and a second set of planchettes configured to luminesce when a second frequency of light is cast on the first planchettes. The first frequency may be different from the second frequency. The first and second set may comprise one planchette or a plurality of planchettes. The first set of planchettes may be configured so that they only luminesce when light of a first specific frequency is cast on the planchettes. The second set of planchettes may be configured so that they only luminesce when light a second specific frequency is cast on the planchettes.
This disclosure has described several variables germane to the design of planchettes, including shape, visible, and UV substrate color, substrate composition and security fibers, visible and UV surface artwork, and designs for transmitted light inspection. Although each was explored in isolation through the examples in this disclosure, an idealized planchette design (or designs) could take all these factors into consideration simultaneously and combine them in ways that facilitate ergonomic inspection, prevent easy simulation, and respond to several methods of visual and machine inspection, including the many possible combinations of reflected light, UV light, transmitted light, infrared light, angles of illumination and response, cameras, optical filters, sensors and magnification. Inspection can also be by instrumental analysis techniques including, but not limited to, chemical ionization mass spectrometry and chemic mass spectrometry. The security substrate design concepts presented in prior work on combining security fibers are equally applicable to planchettes, such that multiple planchette types with different characteristics and intended for different modes of inspection could be combined in a single substrate. See, e.g., Joel Zlotnick et al., “Strategies for Optimisation of Security Fibres,” https://platform.keesingtechnologies.com/security-fibres-optimisation/, Dec. 11, 2019, and Joel Zlotnick et al., “Strategies for Optimizing Planchettes,” https://platform.keesingtechnologies.com/strategies-for-optimizing-planchettes/, Feb. 23, 2022, the entire disclosures of which are incorporated herein by reference.
Image Detection Apparatus and Process
The following describes some examples of image detection apparatus and process for authenticating an article of manufacture such as a security document or substrate having planchettes and the like as security features.
The authentication system 300 may be used to determine whether an article of manufacture is genuine. The article of manufacture may be a security document or substrate having security or anticounterfeiting features including one or more planchettes as counterfeiting deterrents, such as those presented in this disclosure. The authentication process may be implemented using machine readable instructions that are executed by any processing or computing systems now known or developed later. The machine-readable instructions may be embodied in software stored on a tangible medium such as a CD-ROM, a floppy disk, a hard drive, a digital versatile disk (“DVD”), or a memory associated with a processor and/or embodied in firmware or dedicated hardware in a well-known manner. Further, persons of ordinary skill in the art will readily appreciate that many other methods of implementing the authentication process may alternatively be used. For example, the order of execution of the process steps may be changed, and/or some of the steps described may be changed, eliminated, or combined.
Here, the term computer system includes a processing system such as processing system 4010 and a memory such as memory 4015 accessible to the processing system.
The processing system includes at least one hardware processor, and in other examples includes multiple processors and/or multiple processor cores. In one embodiment, a computer system is a standalone device. The processing system in yet another example includes processors from different devices working together. In embodiments, a computer system includes multiple processing systems that communicate cooperatively over a computer network.
The following discussion explains how the logic, that implements the foregoing operations, transforms the hardware processor of computer system 4000 into a specially-programmed electronic circuit.
A hardware processor is a complex electronic circuit designed to respond to certain electronic inputs in a predefined manner. The inputs to a hardware processor are stored as electrical charges. The hardware processor interprets the electrical charge of a given memory circuit as having one of two binary values, namely, zero or one.
A given hardware processor has electrical circuitry designed to perform certain predefined operations in response to certain ordered sets of binary values. The electrical circuitry is built of electronic circuits arranged or configured to respond to one set of ordered binary values one way and to another set of ordinary values another way, all in accordance with the hardware design of the particular hardware processor. A given set of ordered binary values to which the hardware processor is designed to respond, in a predefined manner, is an instruction.
The collection of instructions to which a given hardware processor is designed to respond, in a predetermined manner, is the native instruction set of the processor, also referred to as a native instruction set of codes. The native instruction set for one hardware processor may be different from the native instruction set for another hardware processor, depending on their manufacture. To control a given hardware processor, it is necessary to select an instruction or a sequence of instructions from the predefined native instruction set of that hardware processor.
A sequence of codes that a hardware processor is to execute, in the implementation of a given task, is referred to herein as logic. Logic is made up, therefore, not of software but of a sequence of codes or instructions, selected from the predefined native instruction set of codes of the hardware processor, and stored in the memory.
Returning to
The memory 4015 includes the predefined native instruction set of codes 4035, which constitute a set of instructions 4040 selectable for execution by the hardware processor 4025. In an embodiment, the set of instructions 4040 include logic 4045 representing the central processing server 354 as illustrated in
The various logic 4045 is stored in the memory 4015 and comprises instructions 4040 selected from the predefined native instruction set of codes 4035 of the hardware processor 4025, adapted to operate with the processing system 4010 to implement the process or processes of the corresponding logic 4045.
The inventive concepts taught by way of the examples discussed above are amenable to modification, rearrangement, and embodiment in several ways. For example, this invention may be applicable in other environments involving other markings different from those in the examples as presented above. Different colors from those described above may be used. The number of printing plates used to form the markings can vary (increase or decrease) from the above examples. The configuration of each of the printing plates can be modified to achieve similar or different functional results or effects. Accordingly, although the present disclosure has been described with reference to specific embodiments and examples, persons skilled in the art will recognize that changes may be made in form and detail without departing from the spirit and scope of the disclosure.
An interpretation under 35 U.S.C. § 112(f) is desired only where this description and/or the claims use specific terminology historically recognized to invoke the benefit of interpretation, such as “means,” and the structure corresponding to a recited function, to include the equivalents thereof, as permitted to the fullest extent of the law and this written description, may include the disclosure, the accompanying claims, and the drawings, as they would be understood by one of skill in the art.
To the extent the subject matter has been described in language specific to structural features or methodological steps, it is to be understood that the subject matter defined in the appended claims is not necessarily limited to the specific features or steps described. Rather, the specific features and steps are disclosed as example forms of implementing the claimed subject matter. To the extent headings are used, they are provided for the convenience of the reader and are not to be taken as limiting or restricting the systems, techniques, approaches, methods, or devices to those appearing in any section. Rather, the teachings and disclosures herein can be combined or rearranged with other portions of this disclosure and the knowledge of one of ordinary skill in the art. It is intended that this disclosure encompass and include such variation.
The indication of any elements or steps as “optional” does not indicate that all other or any other elements or steps are mandatory. The claims define the invention and form part of the specification. Limitations from the written description are not to be read into the claims.
This is a nonprovisional application that claims the benefit of priority from U.S. Provisional Application No. 63/313,178 entitled “Systems and Methods of Using Planchettes to Detect Unauthorized Copying or Counterfeiting in Articles of Manufacture,” filed on Feb. 23, 2022, the disclosure of which is incorporated herein by reference in its entirety.
The claimed subject matter was made by one or more employees of the United States Department of Homeland Security in the performance of official duties. The U.S. Government has certain rights in this invention.
| Number | Date | Country | |
|---|---|---|---|
| 63313178 | Feb 2022 | US |
