The present invention relates generally to personalization of secure documents, and more particularly to personalization by producing an image on a document by selectively revealing colored, black, and white pixels by exposing one or more layers of photon-sensitive materials to photons.
Many forms of physical media require both mass-production and end-user personalization. For example, identity cards may need to be produced for very large population pools, yet every individual card has to uniquely identify the person carrying the card. The high-volume manufacturing phase may be performed on relatively expensive equipment because the equipment cost may be amortized over very large production runs. On the other hand, the end-user personalization may be preferably carried out at customer locations in relatively low volumes, thus, requiring much lower equipment costs.
For many identity cards, security of all information on the card, whether digitally recorded or physical features of the card, is of paramount importance. The security is sometimes tied to some features that reveal whether the media has physically been tampered with. One mechanism for thwarting attempts to tamper with identity cards is lamination. By securing the physical media in a lamination layer that may not delaminated without destroying the physical pristineness of the media goes very far to protect the security integrity of media.
One very important mechanism for tying an individual to an identity object is the placement of a person's photograph on the identity object. Driver's licenses, passports, identity cards, employee badges, etc., all usually bear the image of the individual to whom the object is connected.
Laser engraving provides one prior art technique for personalizing an identity card post-issuance with a photograph.
Traditionally polycarbonate (PC) ID products have been personalized using laser-engraving technology. This is based on a laser beam heating carbon particles inside specific polycarbonate layers to the extent that the polycarbonate around the particle turns black. While the particles could be chosen to be something else than carbon, it is the intrinsic property of polycarbonate that creates the desired contrast and number of gray levels to produce, for example, a photograph. The gray tone is controlled by the laser power and speed of scanning across the document. This technology is standard on the ID market. However, a limitation of this technique is that color images may not be produced in that manner.
In certain markets and applications it is desirable to have identity cards with color images.
Traditionally color photographs have been placed in identity cards using Dye Diffusion Thermal Transfer (D2T2) technology, which has been available for PVC and PET products. Recently the development in the D2T2 technology has made it possible to color personalize also polycarbonate cards. This technology requires a smooth printed surface and the printed image must be shielded with an overlay film, which can also be holographic type. Gemalto S/A of Meudon, France has developed a desk-top D2T2 solution which has been available on the market since the autumn 2007.
A drawback to surface printed color personalization is that it is not as secure as the laser engraved photos and data that are situated inside the polycarbonate layer structure as illustrated in
In another prior art alternative, a color image may be produced using digital printing before the product is collated. This allows for high quality images placed on identity cards. Yet this technology has many drawbacks: the personalization and card body manufacturing must happen in the same premises, which furthermore typically have to be in the country of document issuance because governmental authorities dislike sending civil register data across borders, the color printed photographs prevent the PC layers from fusing to each other, and if any of the cards on a sheet is maculated in further production steps, the personalized card must be reproduced from the beginning of the process leading to a highly complicated manufacturing process.
U.S. Pat. No. 7,368,217 to Lutz et al., Multilayer Image, Particularly a Multicolor Image, May 6, 2008 describes a technique in which color pigments are printed on collated sheets and each color may be bleached to a desired tone using a color sensitive laser.
From the foregoing it will be apparent that there is a need for an improved method to provide a mechanism for placing images on identity cards and the like using a mechanism that produces secure tamper proof color images during a personalization phase using inexpensive customer-premises equipment.
a) through 3(c) are cross-section views of three alternative embodiments of the identity card illustrated in
a) and (b) are illustrations showing how the various layers set forth in
In the appended figures, similar components and/or features may have the same reference label. Further, various components of the same type may be distinguished by following the reference label by a dash and a second label that distinguishes among the similar components or by appending the reference label with a letter or a prime (′) or double-prime (″). If only the first reference label is used in the specification, the description is applicable to any one of the similar components having the same first reference label irrespective of the second reference label appended letter, or prime.
In the following detailed description, reference is made to the accompanying drawings that show, by way of illustration, specific embodiments in which the invention may be practiced. These embodiments are described in sufficient detail to enable those skilled in the art to practice the invention. It is to be understood that the various embodiments of the invention, although different, are not necessarily mutually exclusive. For example, a particular feature, structure, or characteristic described herein in connection with one embodiment may be implemented within other embodiments without departing from the spirit and scope of the invention. In addition, it is to be understood that the location or arrangement of individual elements within each disclosed embodiment may be modified without departing from the spirit and scope of the invention. The following detailed description is, therefore, not to be taken in a limiting sense, and the scope of the present invention is defined only by the appended claims, appropriately interpreted, along with the full range of equivalents to which the claims are entitled. In the drawings, like numerals refer to the same or similar functionality throughout the several views.
An embodiment of the invention, provides a mechanism by which physical media such as identification cards, bank cards, smart cards, passports, value papers, etc. may be personalized in a post-manufacturing environment. This technology may be used to place images onto such articles inside a lamination layer after the lamination layer has been applied. In an alternative embodiment, a protective lamination layer is added to the identity card after personalization. Thus, the articles, for example, smart cards, may be manufactured in a mass produced fashion in a factory setting and personalized on relatively inexpensive and simple equipment at a customer location. The technology provides a mechanism for thus personalizing articles, such as smart cards, bank cards, identity cards, with an image that is tamper resistant. Herein, the purpose of providing a clear narrative, the term identity card is used to refer to the entire class of physical media to which the herein-described techniques may be applied even if some such physical media are not “cards” in a strict sense. Without limiting the application of the term identity card it is intended to include all such alternatives including but not limited to smart cards (both contact and contactless smart cards), driver's licenses, passports, government issued identity cards, bankcards, employee identification cards, security documents, personal value papers such as registrations, proofs of ownership, etc.
In a typical smart card lifecycle, a card is initially manufactured in a factory setting. The manufacturing step includes placing an integrated circuit module and connectors onto a plastic substrate, typically in the shape of a credit card. The integrated circuit module may include systems programs and certain standard applications. The card may also be imprinted with some graphics, e.g., the customer's logo.
Next the card is delivered to the customer.
The customer, for example, a government agency, a corporation, or a financial institution, who wishes to issue secure identification cards to its customers, the end-users of the cards, next personalizes the cards. Personalization, “perso” in industry parlance, includes the customer placing its application programs onto the card, and end-user specific information on the card. Perso may also include personalizing the physical appearance of the card for each end-user, e.g., by printing a name or photograph on the card.
Once the card has been personalized, the card is issued to the end-user, e.g., an employee or a client of the customer, step 40.
Other identity cards have similar life cycles.
As anti-counterfeiting measures, the top PC layer 59 may include some embossing 67 and a changeable laser image/multi laser image (CLI/MLI) 69. To further enhance security the card 50 may include features such as a DOVID 65, i.e., a Diffractive Optical Variable Image Device such as a hologram, kinegram or other secure image, and a Sealy's Window 63 (a security feature, provided by Gemalto S. A., Meudon, France, in which a clear window that turns opaque upon tampering is provided in the card). The card 50 may also contain a contact less chip and antenna system 61.
During personalization the laser-engravable transparent layers 57 and 53 may be provided with a gray-scale image and identifying text.
The identity card 100 may have been printed with a company-logo or other graphic. Through a unique process and manufacture described in greater detail herein below, the identity card 100 contains a color image 203, for example, a photograph of the intended end-user, printed in an image area 205. The identity card 100 may further have been personalized with a printed name 207. The printed name 207 may be applied to the card using the same techniques as described-herein for applying an image 203 to the identity card 100.
a) is a cross-section of the identity card 100 of
A print-pixel grid 111 is located on one surface of the substrate 107 (substrate 107 is meant herein to refer to any of the internal layers of the card 100, e.g., similar to the opaque PC layer 55, either transparent PC layer 53 or 57, or internal layers constructed from alternative materials) in an area of the substrate corresponding to the image area 205. The print-pixel grid 111, which is described in greater detail herein below in conjunction with, for example,
The print-pixel grid 111 is covered by a transparent photon-sensitive layer 105. The transparent photon-sensitive layer 105 is manufactured from a material that converts from being transparent to some level of opaqueness upon being exposed to photons of particular wavelength and intensity. Suitable materials include carbon-doped polycarbonate. Traditionally polycarbonate (PC) ID products have been personalized using laser-engraving technology. This personalization is based on a laser beam heating carbon particles inside specific polycarbonate layers to the extent that the polycarbonate around the particle turns black. While the particles could be materials other than carbon, it is the intrinsic property of polycarbonate that creates the desired contrast and number of gray levels to allow creation of a photographic image. The gray tone is controlled by the laser power and speed of scanning across the image area 205. Thus, a carbon-doped transparent PC layer may be selectively altered into an opaque layer along the darkness scale by exposing select location with a Nd-YAG laser or Fiber Laser. An Nd-YAG laser emits light at a wavelength of 1064 nanometers in the infrared light spectrum. Other Nd-YAG laser wavelengths available include 940, 1120, 1320, and 1440 nanometers. These wavelengths are all suitable for turning a transparent PC layer opaque black or partially opaque with an intensity in the range of 10 to 50 watts. In a typical application, the Nd-YAG laser is scanned (in the manner discussed in greater detail below) over the image area for a duration of approximately 4 seconds exposing specific locations as required. Fiber lasers that are suitable for turning the transparent PC layer opaque or partially opaque operate in wavelengths in the range of 600 to 2100 nanometers. While some specific lasers and wavelengths are discussed herein above, any alternative photon source, e.g., a UV laser, that converts a location on a transparent PC layer opaque may be employed in lieu thereof.
The transparent photon-sensitive layer 105 is covered with an opaque layer 103 that may be altered into a transparent layer by exposure to photons in a particular wavelength and intensity. Suitable materials for the opaque-to-transparent photon-sensitive layer include a white bleachable ink that may be laid down on top of the transparent-to-opaque layer 105 through thermal transfer or die sublimation, for example. Examples, include SICURA CARD 110 N WA (71-010159-3-1180) (ANCIEN CODE 033250) from Siegwerk Druckfarben A G, Sieburg, Germany, Dye Diffusion Thermal Transfer (D2T2) inks available from Datacard Group of Minnetonka, Minn., USA or Dai Nippon Printing Co., Tokyo, Japan. Such materials may be altered selectively by exposing particular locations by a UV laser at a wavelength of, for example, 355 nanometers or 532 nanometers with an intensity in the range of 10 to 50 watts for a few milliseconds per addressable location (sub-sub-pixel). To alter the sub-sub-pixels in the opaque-to-transparent layer 103 the laser is continuously scanned over the image area exposing those sub-sub-pixels that are to be altered from opaque white to transparent in the opaque-to-transparent layer 103 by ink bleaching or evaporation. In an alternative embodiment, the same UV laser wavelength that removes the ink of the opaque-to-transparent layer 103 may also be used to alter the carbon-doped transparent-to-opaque layer 105 below the removed sub-sub-pixels of the opaque-to-transparent layer 103 when there is residual power available from the UV laser.
In an alternative embodiment the opaque-to-transparent layer 103 is a photon-sensitive layer that is amenable to a dry photographic process that requires no chemical picture treatment. One example is spiropyran photochrom with titanium oxide (similar to the material used to produce with PVC). This process is based on the photochemical behavior of colored complexes between spiropyrans and metal ions.
In an alternative embodiment, illustrated in
The photochromic effect of spiropyran-based opaque-to-transparent layer 103 may be achieved by exposure to visible or ultraviolet light. The preferred intensity is in the range of 50 to 200 watts at a distance of 30 to 300 millimeters for a duration of 10 to 300 seconds.
The principle of preparation of emulsions for a dry color printing process has been patented by Prof. Robillard (US Pat. Appl. 2004259975). The results of feasibility investigation is described in a J. Robillard et al, Optical Materials, 2003, vol. 24, pp 491-495. The process involves photographic emulsions that require exclusively light of the UV or visible range for producing and fixing images. The emulsions include colored photochromic dyes and a system for amplification and exhibit photosensitivity comparable to those of the known silver-containing conventional materials. In general, this process is applicable for any kind of supports (paper, tissues, polymeric films).
Finally, the identity card 100 is covered with an upper lamination layer 109a and a lower lamination layer 109b. The lamination layers 109 provide security in that they protect the image 203 produced in the image area 205 from physical manipulation. The upper lamination layer 109a should be transparent to the photon wavelengths used for altering the transparent-to-opaque layer 105 and the opaque-to-transparent layer 103. Furthermore, the lamination temperature should be low enough as to not alter the transparent-to-opaque layer 105 or opaque-to-transparent layer 103, for example, in the range of 125 to 180 degrees Celsius. Suitable materials include PVC, PVC-ABS, PET, PETG, and PC.
c) is a cross-section view of yet another alternative embodiment for an identity card 100″ that may be personalized with a color image produced on the card during the personalization phase. A photon-sensitive print-pixel grid 111″ is located above a carbon-doped PC layer 105 which in turn is located above a white opaque PC layer 107″. The print-pixel grid 111″ in this case consists of multiple sub-sub-pixels that may be selectively removed by exposure to photons of appropriate wavelength and intensity. The image area 205 may be customized with a color image 203 by selectively removing colored sub-sub-pixels from the photon-sensitive pixel-grid 111″ and by subjecting the carbon-doped PC layer 105 selectively to photon-energy that alters select portions thereof from transparent to black.
While it is desirable to prepare the entire card during the manufacturing phase of the card life-cycle, in some embodiments applying the technology described herein that is not practical because the upper lamination layer 109a could prevent evaporation of dyes from the opaque-to-transparent layer 103 or 111″. Therefore, if the alteration of one of the photon-sensitive layers requires evaporation or some other form of material removal in the process of transforming from one state to another, e.g., from opaque to transparent, the upper lamination layer 109a may be added during the personalization phase, for example, after the image area 205 has been personalized as described herein. Such lamination may be performed using DNP CL-500D lamination media from Dai Nippon Printing Co., Tokyo, Japan or other suitable lamination technology.
Turning now to the structure of the print-pixel grid 111, for which a small portion is illustrated in
The term print-pixel is used herein to the equivalent of a pixel in a digital image that is printed in the print-pixel grid and having a plurality of sub-pixels that each form a portion of the print-pixel, and the corresponding areas in the photon-sensitive layers that cover the image area 205. A sub-pixel is a single-color area of the print-pixel. A sub-sub-pixel is a single addressable location in a sub-pixel. Thus, a sub-pixel is composed of one or more sub-sub-pixels. A sub-sub-pixel may take its exposed color from either the print-pixel grid or any of the photon-sensitive layers.
a) illustrates the manipulation of the opaque-to-transparent layer 103 and the transparent-to-opaque layer 105 to produce desired colors for a print-pixel 501 by displaying the cross-section of each of a black print-pixel 501a, a white print-pixel 501b, a red print-pixel 501c, and a blue print-pixel 501d. For each print-pixel 501a through 501d illustrated in
b) illustrates the manipulation of the photon-sensitive print-pixel layer 111″ and the carbon-doped transparent layer of the alternative identity card 100″ illustrated in
While
Turning now to the computation of masks for the transparent-to-opaque layer 105 and the opaque-to-transparent layer 103. The determination of which sub-sub-pixels 505 are to be left opaque white, are to be turned into opaque black, or are to reveal the underlying color from the print-pixel grid 111 is controlled by a mask for each of the photon-sensitive layers. These masks may, for example, have an on/off value for each sub-sub-pixel in the image area 205 or a value indicate the level of opacity the particular photon-sensitive layer is to provide for each sub-sub-pixel.
The process 110 accepts as input a digital image 121, for example, in the .bmp format. A .bmp format image file 121 is a bitmap for each pixel in an image to particular RGB (red-green-blue) values. The process 110 converts the image file 121 into an exposure mask white 125a and an exposure mask black 125b. These exposure masks 125 are provided as input to a controller 355 (
It is assumed here that there is a one-to-one correspondence between each pixel of the source image 121 to each print-pixel 501 of the print-pixel grid 111. Otherwise, a pre-processing conversion algorithm can be applied. Furthermore, the process 110 is described with respect to square print-pixels 501 with three rectangular sub-pixels 503 for green, blue and red, respectively, as illustrated in
From one perspective an objective of the process 110 is to determine how much of each color sub-pixel 503 is to be visible for each print-pixel in the resulting image 203. A second objective is the determination of the opacity for the transparent-to-opaque layer 105 because that layer may take on varying degrees of opacity. Third, the process 110 determines the ratio between black and white fully obscuring sub-sub-pixels and the locations for such sub-sub-pixels.
The brightness of each source pixel is determined, step 127, by the following formula:
where red, green, and blue are numeric component of the source image and have values in the range zero and max (255). The resulting brightness value thus is in the same range (0-max (255)).
Next whitelevel adjusted RGB values are computed, step 129. This calculation begins with the computation of whitelevel:
whitelevel=min(red,green,blue)
Adjusted RGB values are computed by:
AdjustedRED=red−whitelevel
AdjustedGREEN=green−whitelevel
AdjustedBLUE=blue−whitelevel
where red, green, and blue are the RGB values in the source image.
Next a hue enhancement is computed and the adjusted RGB values are further adjusted for the hue enhancement, step 131, as follows:
This calculation produces for each print-pixel 501 the portion size of each red, green, and blue sub-pixel to be fully revealed. The portion size is the converted to conform to the number of sub-sub-pixels available for each color sub-pixel:
numSubSubRED=totalSubSub*AdjustedRED÷255
numSubSubGREEN=totalSubSub*AdjustedGREEN÷255
numSubSubBLUE=totalSubSub*AdjustedBLUE÷255
where totalSubSub is the number of sub-sub-pixels 505 per sub-pixel 503 and numSubSubRED, numSubSubGREEN, and numSubSubBLUE each are floating point values corresponding to the number of sub-sub-pixels that would be necessary to cover the sub-pixel 503 with the corresponding portion of red, green, and blue, respectively.
Next, each print-pixel is brightness adjusted, step 133, as follows:
where brightness is the brightness computed in step 127.
Step 133, thus, computes the overall portion of each print-pixel 501 that should be fully opaque black to be used in computations described herein below.
The number of revealed sub-sub-pixels for each color and also the number of sub-sub-pixels for black cover are both victim of quantization error during the computations. For the herein-described case of twelve sub-sub-pixels per sub-pixel, this quantization error does not have an easily perceptible effect on the image for a human viewer, and the quantization errors can be ignored. If a print-pixel is designed with fewer sub-sub-pixels per sub-pixel, then these quantization errors become more noticeable in the produced image quality. The human eye is much more sensitive to brightness errors than color errors, so the priority is to repair the brightness quantization errors. The adjustability of the transparent-to-black photosensitive layer 105 allows an opportunity for correction.
Consider a print-pixel with 5 sub-sub-pixels for each of the three colors (red, green, blue), and a fourth (and much smaller) white sub-pixel made up of a single white sub-sub-pixel (WSSP). Such a print-pixel is a square print-pixel with 4×4 sub-sub-pixels total. Varying the black cover over this single white sub-sub-pixel, provides a mechanism for compensating for the brightness quantization error. This compensation may be performed by, at the beginning of the algorithm, assuming that single white sub-sub-pixel to be black (even if desired pixel overall color is pure white). Then when a brightness quantization error occurs, that white sub-sub-pixel WSSP can be darkened to the desired grayscale level to overcome the quantization error (if more brightness is desired, an additional black-covered sub-sub-pixel is allocated instead to white cover, then the difference made by darkening that single white sub-sub-pixel WSSP). The following is a sample code for an ordering list for the print pixel configuration having 5 colored sub-sub-pixel and one white sub-sub-pixel per sub-pixel:
At this point, knowing how many of each sub-sub-pixels 505 to reveal for each sub-pixel 503, and how many sub-sub-pixels to render black, the number of white sub-pixels is the remainder:
totalWhiteCover=(3*totalSubSub)−totalBlackCover−totalRevealed
Next the sub-sub-pixels that are to be opaque (white or black) are mapped on the grid of sub-sub-pixels 505 that make up the print-pixel 501, step 135. A preference is given to have opacity located on the periphery of the print-pixel 501. This result is achieved by ordering the sub-sub-pixels as to their relative order of priority for being made an opaque sub-sub-pixel. The opaque sub-sub-pixels are located according to that priority ordering until all opaque sub-sub-pixels have been assigned particular locations. If assigning opacity to a particular sub-sub-pixel would render the sub-pixel to which that sub-sub-pixel belong as having too few revealed sub-pixels from the print-pixel grid layer 111, the opacity is assigned to the next sub-sub-pixel in the opacity preference order.
At this point the opacity map 123 has been computed.
Next, the black cover map is computed. That calculation commences with determining the brightness positioning preference, step 137. To achieve sharp representation of brightness boundaries, the source image 121 is analyzed to identify sharp brightness boundaries and to set up a brightness positioning preference for each print-pixel 501; for print-pixels that do not lie on a brightness boundary, no brightness positioning preference is assigned.
For each pixel in the source image 121 direction and magnitude of the greatest brightness contrast is identified by comparing adjacent pixels while ignoring the brightness of the pixel for which a brightness positioning preference is being determined.
Thus, brightness contrasts are determined for the pairs above-below, left-right, aboveLeft-belowRight, aboveRight-belowLeft. As an example, the brightness contrast for the above-below pair is:
brightnessContrast(above,below)=abs(brightness(above)−brightness(below))
If the greatest brightnessContrast for any of these adjacent-pixel pairs is below a pre-defined threshold, e.g., 96/255, the brightnessPositioningPreference is set to none. If the greatest brightnessContrast is above or equal to the threshold, the dark side of the pair with the greatest brightnessContrast is remembered as the brightnessPositioningPreference for the pixel.
Next a darkness ordering preference is computed, Step 139. To determine the preference ordering for placement of black sub-sub-pixels, the sub-sub-pixels 505 that make up the print-pixel 501 are ordered according to their relative nearness to the brightnessPositioningPreference for that pixel. If the brightnessPositioningPreference is none, the sub-sub-pixels 505 located over bright sub-pixels 503 are given preference, i.e., green before red before blue, and secondary preference to sub-sub-pixels located on edges of the print-pixel 501 to reduce sensitivity for printing misalignments. Thus is produced the darkness ordered list of sub-sub-pixels.
Next the opaque black sub-pixels are allocated to the sub-sub-pixels that make up the print-pixel, step 141. Each black opaque sub-sub-pixel is allocated to a sub-sub-pixel in the order provided by the darkness ordered list of sub-sub-pixels. If as a black opaque pixel is to be allocated has not been marked to be opaque in the opacity map 123, that sub-sub-pixel is not marked as black and the next sub-sub-pixel in the darkness ordered list of sub-sub-pixels is considered. If the sub-sub-pixel has been marked to be opaque in the opacity map 123, it is marked to be black.
At the conclusion of this, the process 110 has determined the location of white sub-sub-pixels for the opaque-to-transparent layer 103 and black sub-sub-pixels revealed from the transparent-to-opaque layer 105. Next these maps are translated in to exposure patterns for each of the photon sensitive layers 103 and 105, step 143, resulting in an exposure mask for white 125a corresponding to the opaque-white-to-transparent layer, and an exposure mask for black 125b corresponding to the transparent-to-black layer.
Next, the white layer mask 125a is used to turn-off masking of sub-sub-pixels in the opaque-to-transparent layer 103 that are to be converted from opaque white to transparent, step 153.
The image area is then exposed to photons in the correct wavelength and intensity to convert from opaque to transparent, step 155.
Next, the transparent-to-opaque layer 105 is converted from transparent to black by first unmasking the sub-sub-pixels that are to be converted to black, step 157.
The unmasked sub-sub-pixels are next exposed to the requisite photons to cause the conversion from transparent to black, step 159.
Finally, the image is fixed through a fixation step 161. The method by which the image is fixed, i.e., the method by which the opaque-to-transparent layer 103 and transparent-to-opaque layer 105 are prevented from changing to other states, varies by material. The most straightforward case is for the opaque-to-transparent layer 103 being bleachable ink. Certain bleachable inks have been found to evaporate when exposed to UV laser. Thus, when the opaque-to-transparent layer 103 is transformed from opaque to transparent by removal of the pigmentation from that layer, it is not possible to revert back to being opaque. It is a one-way transformation.
If the opaque-to-transparent layer 103 is a spiropyran layer, the layer may be made fixable by including a fixing material in the layer, e.g., Ludopal as a photoreticulable polymer with benzoyl peroxide as radical initiator. This layer 103 may be fixed through exposure to UV light in the range of 488 nm to 564 nm with a power of approximately 3.5 milliwatts/cm2 for approximately 5 seconds. Suitable equipment includes a black ray lamp B-100 A, No 6283K-10, 150 W from Thomas Scientific of Swedesboro, N.J., U.S.A. As an alternative a spiropyran opaque-to-transparent layer 103 may be fixed using heated rolls, e.g., 3M Dry Silver Developer Heated Rolls at 125 degrees Celsius on medium speed.
Turning now to equipment that may be used for producing an image 203 in an image area 205 of an identity card 100.
The masks 125 are input into a process controller 355. The process controller 355 is programmed to perform the steps of process 150 of
The resulting manufactured card 100 has an image area 205 that consists of the print-pixel layer 111, the transparent-to-opaque layer 105, and the opaque-to-transparent layer 103 all optionally under a laminate layer 109. The cards 100 may now be delivered to customers, step 20.
It should be noted that for the embodiment of an identity card 100″ illustrated in
At the customers' locations, the cards 100 may be personalized for end-users, step 30. This includes rendering an image of the end-user onto the card, step 31, in the manner described herein above by converting an image file into masks 125 that may be used to control equipment that expose select locations of the image area to photons that selectively reveal or conceal sub-sub-pixels of various specified colors. After the image has been created, it is fixed, step 33. Alternatively, the cards 100 may be protected against alteration by adding a filter that filters out photons that would alter the photon-sensitive layers, e.g., by applying a filtering varnish to the card. In yet another alternative, an additional transparent layer is included between the upper lamination layer 109a and the photon-sensitive layers 103 and 105. This additional layer is also a photon sensitive layer. This additional layer, upon being exposed to photon energy or heat, transforms from being transparent to the wavelengths that transform the opaque-to-transparent layer 103 and transparent-to-opaque layer 105 to being opaque to those wavelengths thereby blocking any attempts to alter the image 203.
As described herein above, in some embodiments the change from opaque to transparent relies on evaporating away ink from the opaque-to-transparent layer 103. Therefore, the perso phase 30 may conclude with a lamination layer 17b after the personalization of the image area 205. The post-person lamination step 17b also provides an alternative opportunity for laying down a filter that blocks photons that could other wise further alter the image 203, in which case the fixation step 33 and the lamination step 17b may be considered to be one step.
Finally the card 100 may be issued to an end-user 40.
Thus, the smart card life cycle has been successfully modified to provide for post-issuance personalization by placing an end-user image on the card under a laminate thereby improving the personalization of the card while providing for a high degree of tamper resistance.
From the foregoing it will be apparent that a technology has been presented herein above that allows for personalization of sensitive articles such as identification cards, bank cards, smart cards, passports, value papers, etc. in a post-manufacturing environment. This technology may be used to place images onto such articles inside a lamination layer which may be applied before or after the lamination layer has been applied. Thus, the articles, for example, smart cards, may be manufactured in a mass produced fashion in a factory setting and personalized on relatively inexpensive and simple equipment at a customer location. The technology provides a mechanism for thus personalizing articles, such as smart cards, bank cards, identity cards, with an image that is tamper proof.
While the above description focuses on smart card personalization, which is a field in which the above described technology is ideally suited, the reliance on smart cards herein should only be considered as an example. The technology is also applicable to other devices and documents that benefit from secure personalization with an image. Some examples include identification cards, bank cards, smart cards, passports, value papers.
Although specific embodiments of the invention have been described and illustrated, the invention is not to be limited to the specific forms or arrangements of parts so described and illustrated. The invention is limited only by the claims.