Patent Description:
<CIT>; <CIT>; <CIT>, discloses a credit card having a plastic base material with a transparent area that forms a magnifying lens, such as a Fresnel lens, that permits the card to be used as a magnifying glass, such as for being able to read small print on transaction receipts. <CIT>, discloses a transaction card having a transparent window in which the window has collimating properties to focus LED light.

<CIT> discloses a card having a plastic base with a transparent window having a fixed set of elongated segments printed on it, which when superimposed over a display of dynamic visual code combined with the set of elongated segments, reveals the visual code to a viewer looking through the window. Thus, such cards have printed information on the window, and the printed information on the window is functional in nature, in that the pattern must align with the elongated segments that are combined with the visual code.

Providing a card that is primarily metal, ceramic, or a ceramic-coated body, such as metal, enables cards with a certain look and feel (e.g. heft) not available with a plastic card, and providing a transparent window in such cards provides a desirable differentiation from other card offerings. Metal and/or ceramic cards are generally more expensive to produce, and therefore may be presented as a luxury card targeted to card holders who have a net worth above a certain threshold, who are members of a select group of high-value customers to the card issuer, and/or who are willing to pay a substantial annual fee. A carrier of such a luxury card may not wish to admit of any need for a magnifying glass, and thus may not desire for a transparent window with magnification or collimation. The carrier of such a card may prefer that the majority of the center of the transparent window have no printing that obscures the view through the card, or that the window be adorned with a decorative, non-functional pattern, rather than the functional pattern of elongated segments, such as the patterns described in <CIT>, which patterns tend to be aesthetically unpleasing. Embedding a transparent window in a metal and/or ceramic frame may present different manufacturing and structural challenges and opportunities different from the types of cards described in the references noted above.

Users and producers of cards frequently wish to incorporate designs that are visibly and/or tactilely perceptible from at least one surface of a card. For example, <CIT> discloses a gemstone-carrying card in which gemstones are embedded in a plastic card. Card issuers and cardholders may have an interest in creating designs that provide a look similar to a pattern of gemstones, without the labor-intensive steps and expense of having to embed numerous multiple individual gemstones in the card.

<CIT> illustrates for example a substrate for contactless transaction card, which is equipped with an integrated chip (IC) connected to at least one organic light-emitting diode (OLED) and an inductively powered tag.

<CIT> Alrelates to a dual interface transaction card includes a metal card body having first and second surfaces. A contact-only transaction module is secured in the card body, the contact-only transaction module including contact pads disposed on the first surface of the card body and including a first transaction circuit. A contactless transaction module is secured in a void in the metal card body. The contactless transaction module includes a second transaction circuit and an antenna.

<CIT> concerns a smartcards having a metal card body with a slit overlapping a module antenna of a chip module or multiple metal layers each having a slit offset or oriented differently than each other. A front metal layer may be continuous, and may be shielded from underlying metal layers by a shielding layer. Metal backing inserts reinforcing the slits may also have a slit overlapping the module antenna. Diamond like coating filling the slit.

Further advantageous embodiments are defined in the dependent claims.

Referring now to the drawings, <FIG> depict an exemplary transaction card <NUM> comprised of a relatively thick body <NUM>, a window insert <NUM>, and a backing layer <NUM>. Body <NUM> has a thickness (T), a front face <NUM>, a back face <NUM>, and a hole <NUM> extending from the front face to the back face. As depicted in <FIG>, hole <NUM> has a circular periphery, but it should be understood that the periphery of the hole may take any geometric form (oval, triangular, square, rectangular, or any regular or irregular polygonal form having <NUM> or more sides), or it may have a periphery comprising a combination of curved and/or linear sections that do not conform to any of the foregoing geometric categories. It should also be understood that the transparent or translucent window(s) may be any size as characterized by its overall area, so long as its overall area is less than the area of the body <NUM>, and preferably fully contained within the area of the card (i.e. the periphery of the window is located entirely radially inward of the periphery of the body).

Non-magnifying window insert <NUM>, having a front face <NUM>, back face <NUM>, the same thickness (T) as the body <NUM>, and a periphery matching the periphery of hole <NUM>, is disposed in the hole. The window may be both non-magnifying and non-collimating. By "matching" periphery, it is meant that the window insert has an identical periphery as the periphery of the hole, but is sufficiently smaller in diameter (or the equivalent thereof) to be inserted in the hole without having to force fit it, leaving no gap, or a gap that is minimal and nearly imperceptible to the human eye, at the interface between the inside edge of the hole and the outer edge of the insert. Similarly, by the "same" thickness, it is meant that the window insert and the metal body are of the same thickness to a desired level of precision within an acceptable tolerance, recognizing that such a tolerance may include a difference in thickness that is perceptible to the human touch or a difference in thickness that accounts for the thickness of the printed layer on the body.

In some embodiments, the window insert is devoid of functional printed content on either its front or back face (or embedded therein). By "devoid of functional printed content," it is meant that the insert in some embodiments has no content printed on it whatsoever (not shown), or in other embodiments, any content printed thereon (e.g. ship graphic <NUM> depicted in <FIG>) is purely decorative in nature and not, for example, for use in connection with an authentication or verification scheme implemented by placing the window over a corresponding graphic. Instead of or in addition to printing, the graphics or other content disposed in the window may also be engraved, etched, or otherwise cut into the window. Engraved, etched, or otherwise cut content in the window may also be non-functional, including aesthetic content in the nature of 3D reliefs, such as to provide a cameo-like appearance. In other embodiments, as described further herein, the window may comprise electronics (e.g. an LED) mounted thereon or therein, in which case preferably "invisible" or minimally visible (not visible to the naked human eye in ambient lighting without careful inspection) traces may be printed or otherwise disposed on or in the window. Such traces may connect the LED to electrical traces in the body, which traces in the body may connect to a concealed power source in the body or may connect to a source and/or recipient of electrical signals. In some embodiments, the LED may comprise a backlit LED. The window may comprise a light guide that transmits light from a light source, such as an LED located at an input surface of the light guide to an output surface of the light guide. While it is understood that all electrical signals have some inherent power, the term "power" as used herein refers to power for powering the electrical feature, whereas the term "electrical signals" as used herein refers to a signal that is not for providing power, but rather for communicating information. Thus, the electrical impulses traveling to and from the electrical feature to any connected components may comprise power, electrical signals, or a combination thereof.

By "non-magnifying," it is meant that the window insert is not functional as a magnifying lens (i.e. objects at a given distance viewed through the window insert appear the same size than if not viewed through the window). By non-collimating, it is meant that the window does not focus radiation of any wavelengths (not limited to visible light) that pass through the window toward a focal point. The window may be light dispersing. The window insert is non-metal, and preferably comprises polished polycarbonate, but may comprise glass or any transparent plastic or resin known in the art. In some embodiments, the window insert may have a primarily transparent or translucent region with one or more different materials inlaid inside it, such as for example, metal, ceramic, wood, crystal, genuine or synthetic gemstones, mother-of-pearl, leather, or the like. Although referred to herein as "transparent," the window may cause sufficient light scattering and diffusion that objects viewed through the window are not visible with perfect clarity. The window alone is more transparent than the combination of the window and the backing layer (and any layers on top of the window). The materials of the window insert may be selected to lie anywhere in the range between translucent (where objects viewed through the window cannot be seen clearly at all) and transparent (where objects viewed through the window can be seen clearly). At a minimum, the window is translucent to the spectrum of light visible to the typical human eye (i.e. wavelengths from about <NUM> to <NUM>; and frequencies in the range of about <NUM>-<NUM> THz). In preferred embodiments, the window is not tinted. Thus, for example, when stacked in a cardholder's wallet, the window may permit the user to see the card located immediately below it with some clarity.

In some embodiments, it may be desirable for the window to be electrically conductive or to have electrically conductive features. For example, in some embodiments, the window may comprise glass or another non-conductive material, such as a plastic resin, coated with a conductive coating, such as an indium-tin-oxide coating or an electrically conductive ink. In other embodiments, the window may comprise in whole or in part an electrically conductive plastic (i.e. polycarbonate or another plastic material formed from a conductive plastic resin).

In some embodiments, as depicted in <FIG>, card <NUM>, <NUM>, <NUM>, <NUM> may have electronics <NUM>, <NUM>, <NUM>, <NUM> such as an integrated circuit, an LED inlay, a switch, or any other electronic feature known in the art, incorporated in the window <NUM>, <NUM>, <NUM>, <NUM> with "invisible" traces <NUM>, <NUM>, <NUM>, <NUM> comprising ITO or other printed conductive inks or adhesives, which may connect the electronics to electrical connections <NUM>, <NUM>, <NUM> at the interface between the window and the body <NUM>, <NUM>, <NUM> at the periphery of the hole. In some embodiments, the electrical connections <NUM>, <NUM>, <NUM> may then connect to a power source <NUM>, <NUM>, <NUM>, such as a battery or an antenna for harvesting RF power. Thus, for example, an LED display, such as for showing a dynamic code, or for emitting light to provide an indicator of card operability (e.g. illuminated when information is being actively read from the card), may be bonded to or embedded in the window and connected to connection points at the edge of the window with ITO or other printed traces. Electronics may be bonded to the window with a conductive adhesive in whole or just in portions requiring conductivity and/or with non-conductive adhesive in whole or just in portions intended to be non-conductive). The use of printed conductive traces using a thin conductive material that is transparent, translucent, or minimally visible, allows incorporation of electronics in the window without unsightly, readily visible wires or copper traces.

In embodiments with an electrically-powered feature in the window, in which power is supplied to the feature from a power source embedded in the body, as depicted in <FIG>, the power may connect to the feature inductively or by physical traces, wherein physical traces in the body connect to physical traces in the window across a conductive interface that bridges any gap between the window and the body. The conductive interface <NUM>, <NUM>, <NUM> may comprise, for example, solder, wire bonding, conductive ink or a conducting adhesive (such as a conducting adhesive patch or ACF tape). The conductive interface <NUM>, <NUM>, <NUM> and any traces <NUM>, <NUM>, <NUM> embedded in a metal body <NUM>, <NUM>, <NUM> are insulated from the metal body by any insulation and methods for disposing the insulation, known in the art. For example, as is known in the art, traces <NUM>, <NUM>, <NUM> may comprise copper traces disposed on a flexible non-conductive substrate disposed in a groove in the body. The conductive interface may simply comprise connecting endpoints of the connecting traces (e.g. <NUM> and <NUM>) or may be somewhat larger than the connecting traces to facilitate alignment when the window is inserted in the hole. Applying the conductive interface <NUM>, <NUM>, <NUM> in the form of a solder bump applied to bridge the gap between traces <NUM>, <NUM>, <NUM> in the window and traces <NUM>, <NUM>, <NUM> in the card after insertion of the window may be particularly effective. To facilitate alignment of electrical connections, the hole and corresponding insert may be non-round or may be keyed, such as with a protrusion in the window that mates with an indent in the hole (or vice versa), so that the insert fits the hole in only a single or limited number of readily differentiated orientations.

In the embodiment depicted in <FIG>, the electronic feature <NUM> disposed in the window <NUM> may be powered entirely by harvesting RF from a card reader inductively, wherein antenna <NUM> is also disposed in the card and connected to the electronic feature without a need for connection to a power source embedded in the body <NUM>. Thus, for example, wherein electronic feature <NUM> is an illuminating feature activated when the card is being read, antenna <NUM> harvests sufficient electricity to power the light and needs no connections to any other features embedded in the card. In other constructions, electronic feature <NUM> and/or antenna <NUM> may be disposed on a surface of the card rather than embedded. In other embodiments, electronic feature <NUM> and/or antenna <NUM> may be connected inductively (or physically by connections akin to any of those shown in <FIG>) to features embedded in the body, such as a power source or, for example, in an embodiments in which the electronic feature is a dual-interface chip, to contacts (e.g. contacts <NUM> depicted in <FIG>) for being read by a contact-based reader.

In another aspect of the invention, the transaction card may comprise a plurality of openings in the front face of the card, as depicted in <FIG>. Specifically, as shown in <FIG>, the plurality of window openings <NUM> in card body <NUM> form a geometric graphic pattern in the shape of a sphere. As shown in <FIG>, the plurality of window openings <NUM>, <NUM>, <NUM> in card <NUM> collectively form an alphanumeric character in the shape of a stylized Q associated with a particular brand of card. As shown in <FIG>, each of the plurality of window openings <NUM> comprises an alphanumeric character arranged together such that the window openings spell a word associated with a particular brand of card. The openings are depicted generically in <FIG> as a collection of different ellipses, and in the cross-sections of <FIG>, they have no identifiable geometry. The pattern and the shapes, sizes, and number of openings that form the pattern, are not limited in any way. The openings may form a recognizable pattern or an abstract pattern. The openings are preferably merely aesthetic in nature and do not serve any function other than to create a suitable pattern or design, which pattern or design may be user-selected or may be selected for difficulty of reproduction. Thus, while the pattern or design may enhance security of the card in a passive way in that the pattern or design by its very existence provides a mark of authenticity that is difficult to reproduce, preferred patterns or designs are referred to herein as "non-functional" because they have no active or interactive functionality.

As depicted in <FIG>, card body <NUM> has a plurality of window openings <NUM>, <NUM>, and <NUM> that penetrate the front face of the card body. Although referred to as the "front" face here and in the claims that follow, the term "front" as used herein in connection with this and other embodiments refers to the side of the card on which the window openings are disposed, which may be side traditionally referred to as the "front" or the "back" side of a functioning card having a magnetic stripe, contacts, and other indicia that may be typically understood to differentiate the "front" and the "back" of the card. Each opening has a different periphery visible from the front side of the card, but all of the windows are located in an area defined by pocket <NUM>, depicted in <FIG>, which pocket defines a single opening in the back face of the card. Insert <NUM> is configured to be disposed in pocket <NUM>. As depicted in <FIG>, <FIG> and <FIG>, card body <NUM> has a recessed ledge <NUM> in the back face surrounding the single opening <NUM>, wherein the insert <NUM> comprises a stepped periphery comprising an outermost region <NUM> having a geometry configured to mate with the recessed ledge, and an innermost region <NUM> configured to fit within the single opening.

In another embodiment, depicted in <FIG>, the body may comprise at least two layers, including a first layer <NUM> that defines the front face <NUM> of the body, and a second part <NUM> that defines the back face <NUM> of the body. The plurality of openings 1110a, 1110b, 1110c penetrate the entire thickness of the layer <NUM>, whereas a single opening <NUM> penetrates the entire thickness of layer <NUM>. Insert <NUM> is configured to fit within opening <NUM>, which defines a pocket when layers <NUM> and <NUM> are combined together. Although not shown with a recessed ledge in layer <NUM>, and corresponding outer peripheral region on insert <NUM>, this feature may also be present in this embodiment. Although depicted as having the same thickness in <FIG>, the two layers <NUM> and <NUM> may have different thicknesses, and either one may be larger than the other. The layers may be adhesively bonded together. Additional layers may also be present, including a transparent or translucent bonding layer between layers <NUM> and <NUM>, that when fills the plurality of openings 1110a-1110c during a lamination step. Backing layer <NUM> may be laminated or otherwise bonded to the back face of the layer <NUM> to keep insert <NUM> in place.

As shown in <FIG>, the insert may consist of member <NUM> alone. In some embodiments, member <NUM> and backing layer <NUM> (and any intermediate or over layers) may be transparent or translucent, such that light is visible through the openings 1110a-1110c. In preferred, embodiments, however, insert <NUM> comprises a non-transparent member that is chosen for aesthetic impact. For example, insert <NUM> may comprise plastic, metal (e.g. having different visual properties than any visible metal in the body), ceramic (e.g. having different visual properties than any ceramic or ceramic coating comprising the body), wood, crystal, mother-of-pearl, stone (including artificial or natural gemstone), natural or synthetic bone or ivory, and natural or synthetic leather. Any of the foregoing may have printing on them (e.g. a printed plastic insert having a graphic that provides visibility into different colors through different openings). Typically, the non-transparent member is opaque, but in other embodiments, it may have some translucence. Member <NUM> may have printing on one or both sides, including in some embodiments, printing visible from one surface of the card that is different from the printing visible from the opposite surface of the card.

Typically, member <NUM> is passive and static, but it may be dynamic, such as a member that is photoluminescent (e.g. that glows in the dark or fluoresces when illuminated by light of a certain wavelength). Member <NUM> may also be a light source, such as an LED, such as more specifically a backlit LED, connected to a power source (not shown) in the same way as described herein for other elements connected to a power source. In still another embodiment, member <NUM> may be a light guide that receives light input from a light source, such as an LED or backlit LED (not shown), at an input surface of the light guide and transmits the light to an output surface. The light may cooperate with the windows to create a pattern that illuminates to indicate, for example, reading of the payment module, but is not limited to any particular purpose.

In still another embodiment, member <NUM> may comprise on OLED (organic light emitting diode). The use of OLED components in transaction cards, generally, has been described in, for example, <CIT>, titled "ORGANIC LIGHT EMITTING DIODE ("OLED") UNIVERSAL PLASTIC" and in <CIT>, titled FLEXIBLE OLED CARD. Although the referenced disclosures describe use of OLED technology in connection with flexible plastic cards, it should be understood that the general technology for providing an OLED display is applicable for incorporation of OLED displays into relatively non-flexible card constructions or flexible card constructions. The flexibility of OLED displays may be particularly useful, however, in connection with overall card constructions having enhanced flexibility (such as flexibility exceeding the ISO/IEC 7810ID-<NUM> standard for transaction cards or meeting or exceeding the ISO/IEC <NUM> standard for thin, flexible cards). Flexible card constructions using OLED displays may further include flexible circuit boards. The term "LED" as used herein with reference to a display should therefore be interpreted as referring to an OLED or a non-organic LED.

In other embodiments, member <NUM> may be an active or dynamic member such as is described in <CIT>, titled "CARD WITH DYNAMIC SHAPE MEMORY ALLOY TACTILE FEATURE". Member <NUM> may be different from the body in any number of ways, including color, texture, reflectance, opacity, and combinations thereof. Member <NUM> may include a display and a processor configured to generate a dynamic security code on the display, such as is described in '<NUM> Application. Any or all of the electronic components described herein may be embedded in the card in any way known in the art, including the methods as described in the '<NUM> Application or in <CIT>, claiming priority from <CIT>, both titled "OVERMOLDED ELECTRONIC COMPONENTS FOR TRANSACTION CARDS AND METHODS OF MAKING THEREOF".

As depicted in <FIG>, the insert may consist of only a single member <NUM> in which, when the card is assembled, an entirety of the front-facing surface of the member is disposed recessed relative to the body front face, meaning the plurality of windows <NUM>-<NUM> are tactilely perceptible in the front face of the card. Thus, for example, when the insert <NUM> comprises mother-of-pearl, lamination of the card will not change this physical relationship among the components. Although preferably non-transparent, member <NUM> may be transparent in some embodiments.

In other embodiments, however, as depicted in <FIG>, the insert <NUM> may comprise a material that is flowable at lamination temperatures, and that may partially or fully flow into the plurality of openings in body <NUM> during a lamination step, such that a plurality of portions <NUM>, <NUM>, <NUM> of the front-facing surface of the non-transparent member protrude into the plurality of openings and are disposed flush with the front face of the body.

In still other embodiments, depicted in <FIG>, an entirety of the front-facing surface of the non-transparent member <NUM> may remain disposed recessed relative to the body front face, and a plurality of transparent or translucent members <NUM>, <NUM>, <NUM> may be disposed in the openings. The transparent or translucent members may comprise an optically clear epoxy that is deposited via automated dispensing in the openings.

In yet other embodiments, depicted in <FIG>, a transparent or translucent layer <NUM> may be disposed over the front face of the body <NUM> and over the plurality of openings such that protrusions <NUM>, <NUM>, and <NUM> from the layer fully or partially flow into the openings during a lamination step, with layer <NUM> remaining in its entirety recessed relative to the body front face.

As depicted in <FIG>, in a multilayer body construction, an intermediate transparent or translucent bonding layer <NUM> may be disposed between the first layer <NUM> and second layer <NUM> of the body such that protrusions <NUM>, <NUM>, and <NUM> fully or partially flow into the openings during a lamination step, with layer <NUM> remaining in its entirety recessed relative to the body front face.

As depicted in <FIG>, transparent or translucent layers <NUM> or <NUM> disposed over the front face and back face of body <NUM>, respectively, may together fully or partially flow into the openings <NUM>, <NUM> during a lamination step. This structure and manufacturing method may be particularly well suited for embodiments in which openings <NUM> and <NUM> are slits, such as the window features <NUM>, <NUM>, <NUM>, <NUM> depicted in <FIG> and <FIG>. Although shown with upper and lower layers, some embodiments may have only one or the other. Although shown with a single discrete upper and a single discrete lower layer, some embodiments may have multiple layers above and/or below the body, and in some of those embodiments, more than one of the layers may contribute to filling the openings. For example, an adhesive layer, which may comprise a carrier with adhesive on both sides, may be interposed between the body and each of the upper and/or lower layers, and the adhesive, the carrier, and the upper or lower layer may all flow into the openings during a lamination step. In other embodiments, adhesive on the underside of the carrier (or disposed directly on the underside of the upper and/or lower layers) may be the only material that flows into the openings.

Although shown with coplanar faces in <FIG>, it should be understood that the flow of material may lead to convex, concave, coplanar, or irregular shaped surfaces of the flowing material on one or both faces of the card. The formation of convex, concave, coplanar, or irregular shaped surfaces may occur in any embodiments in which material flows into the windows/grooves/pockets, and the overall shape may be deliberately controlled to have a particular shape. Similarly, in embodiments in which inserts are pre-formed and assembled into the window / grooves/ pockets, the inserts may also conform to any of the foregoing shapes.

Although all of <FIG> depict a monolithic body, it should be understood that the body in these embodiments may comprise a multi-layer body, such as is depicted in <FIG>.

Referring, for example, to <FIG>, methods and processes for making cards with a window pattern may comprise providing a metal, ceramic, or ceramic-coated body <NUM>) and creating a pocket <NUM> in the body having a periphery and extending from the back face to a location adjacent the front face; then creating a plurality of openings <NUM>, <NUM>, <NUM> extending from the front face into the pocket, the plurality of openings forming a pattern. Insert <NUM> is positioned in the pocket, and then a non-metal backing layer <NUM> adjacent the back face of the body and a back face of the insert is laminated to the body and the insert.

In some embodiments, such as depicted in <FIG>, the step of providing the body may comprise providing a first layer <NUM> that defines the front face of the body and a second layer <NUM> that defines the back face of the body. In such embodiments, the step of creating the pocket comprises creating a through hole <NUM> in the second layer <NUM>, and the step of creating the plurality of openings comprising creating a plurality of through holes 1110a-c in the first layer <NUM>. The openings, pocket, and through holes referred to in these processes may be laser cut, milled, etched, or machined by any method known in the art. For ceramic-coated embodiments, a metal or other material body or body layers may be first coated with ceramic and then the various openings cut and the layers assembled, or the openings may be first cut in the metal or other body and/or the layers assembled, and then the ceramic coating may be applied to the outer surfaces before assembly of the rest of the components.

As depicted in <FIG>, the process may comprise creating a recessed ledge <NUM> in the back face of the body surrounding the pocket <NUM>, and forming the insert <NUM> with a stepped periphery comprising an outermost region <NUM> having a geometry configured to mate with the recessed ledge <NUM>, and an innermost periphery <NUM> configured to fit within the pocket <NUM>.

The step of positioning the insert in the pocket may comprise bonding the outermost region of the insert to the recessed ledge in the body, such as with an adhesive or via non-adhesive mechanical bonding, such as using ultrasonic welding, brazing, or soldering. Using the ledge design in conjunction with a bonding material such as an adhesive, solder, or a brazing alloy, permits bonding on the ledge in a way that minimizes the adhesive or other bonding material flowing into the openings in the front face of the body. In other embodiments, however, it may be desirable for the bonding material, such as a hard-drying clear epoxy, to flow into the openings and fill them to create transparent windows, such as is depicted in <FIG>, in which case no ledge may be desired. Other methods of filling the plurality of openings with clear epoxy may include automatically dispensing the epoxy into the openings after the insert is already in place. Still other methods of filling the openings with a transparent or translucent material may comprise disposing a transparent or translucent coating (such as via lamination of a solid layer, or by application of a spray coating or a liquid layer) over the front face of the body and at least partially filling the plurality of openings with a portion of the clear coating that flows into the plurality of openings, such as during the lamination step.

As noted above, in embodiments in which the insert comprises a material that is flowable during lamination, the process may comprise conducting a lamination step at sufficient heat and pressure to cause protrusions from the insert to fully or partially flow into the plurality of openings during the lamination step. In embodiments with slits, such as those depicted in <FIG>, <FIG>, and <FIG>, the openings may be etched, milled, or created by a laser (although not limited to any particular manner of formation).

As depicted in <FIG>, for ease of manufacture, the step of creating the slit <NUM> may include creating a continuous slit defined by portions <NUM> and <NUM> that extends from payment module pocket <NUM> to an edge of the card. If portions of the slit are not desired to be transparent or translucent for aesthetic reasons, such as portion <NUM>, such portion may be filled with a different type of filler, such as a non-conductive filler that is not transparent or translucent. Such a fill step would be conducted prior to the lamination step that fills the transparent or translucent window portions. The continuous slit defined by portions <NUM> and <NUM>, filled with a non-conductive, card-matching filler in portion <NUM> and filled with a non-conductive, transparent filler in portion <NUM>, may be operable to enable metal frame <NUM> to serve as an amplifying antenna or coupling frame, as disclosed in <CIT>. As shown in <FIG>, in other embodiments, slit <NUM> emanating from the module pocket <NUM> in card <NUM> may be a separate element that is not integrated into the manufacture of the design defined by the transparent or translucent windows <NUM>.

It should be understood that creating an extended opening and filling a portion with a transparent or translucent filler and another portion with a non-transparent / non-translucent portion as depicted in <FIG> is not limited to embodiments in which the slit as a whole connects the payment module pocket to the edge of the card. For example, it may be desirable for ease of manufacture to create a continuous slit and then fill portions of the slit with different fillers for purely aesthetic reasons, and the different fillers may be of any type. For example, fillers may be transparent, translucent, opaque, conductive, non-conductive, or some combination thereof, with different sections of the same continuous opening (or different discrete openings) having different fillers, each filler having a different aesthetic appearance, such as different colors, different textures, and the like. If desired, the filler may comprise a precious metal, such as gold. In other cases, the windows or portions thereof may be illuminated, such as using an LED, as described herein or in any way known in the art. The "filler" (and the insert material) may completely fill or partially fill all or some of the openings in any of the embodiments disclosed herein.

In one embodiment, depicted in <FIG>, a light guide layer <NUM>, comprising a light guide <NUM> and a light source <NUM>, such as a backlit LED, may be sandwiched between metal layers <NUM> and <NUM>. LED <NUM> is positioned adjacent an input to the light guide and the windows <NUM>, <NUM>, and <NUM> are positioned adjacent an output surface of the light guide. Light from the LED <NUM> shines into the light guide and is transmitted out through windows <NUM>, <NUM>, <NUM>. Although depicted in one embodiment in <FIG>, it should be understood that embodiments with a light guide disposed beneath apertures in a metal layer may be provided in any of the other configurations described herein. Windows <NUM>, <NUM>, <NUM>, may have no filler or a transparent or translucent filler, and may be formed via any of the methods or conform to any of the structures described herein.

In some embodiments or designs, rather than creating a continuous slit, such as for the circular shape formed by slits <NUM> and <NUM>, it may be more desirable to create discrete slits with one or more bridges <NUM>, <NUM> of metal between them, for overall structural stability of the card. As depicted in <FIG>, the absence of bridges <NUM> and <NUM> would completely separate the central circular portion from the rest of the metal body. Providing metal separations between adjacent slits is not limited only to embodiments that would prevent separation, however.

As used herein, the term "slit" refers to a gap formed between metal edges, wherein the distance from edge to edge is generally small enough that it is undesirable or impractical to place a separate fill material in the slit prior to a lamination step, and such that the risk of air bubbles forming during lamination is minimal. Lamination conditions can be controlled as desired so that the slit is filled by the overlying and underlying layers without leaving a noticeable indent or partially filled to provide a tactilely distinguishable indent.

In embodiments in which the card body is metal or ceramic coated metal, and the transaction card comprises a payment module configured for "contactless" interface with a card reader (e.g. in which, in at least one operating mode, the transaction circuit embedded in the card inductively couples to a card reader using RFID technology), positioning the window adjacent the module may enhance RF performance of the card, thereby lengthening the distance at which the card may be read in a contactless mode. Specifically, the absence of metal adjacent the module, specifically near the module antenna, may significantly improve (lengthen) the read distance between the card and the card reader required to couple the card and the card reader relative to a card without the transparent window. Optimal distances may be determined by creating a plurality of otherwise identical cards with different window sizes and locations and testing the difference in read distance of the different designs. Generally, the applicant has found read distance percentage improvements in the range of <NUM> - <NUM>%, depending upon the distance in a range of <NUM> - <NUM> between the edge of a metal card and a module. Accordingly, an absence of a significant metal area within that <NUM> - <NUM> distance due to the hole in the metal body to accommodate the window is expected to provide a measurable level of improvement. It should be understood that because dual interface devices operate in both "contactless" and "contact" modes, reference to a device having "contactless" functionality encompasses both modules having only contactless functionality as well as modules having dual-interface functionality.

In some embodiments, the payment module may be located inside the transparent window, in which case a coupling antenna may be positioned surrounding the module using minimally visible traces inside the transparent window. In other embodiments, the entire metal card body may be used as the coupling antenna or a coupling antenna may be embedded in the body, as is known in the art. The minimally visible traces, including antenna traces, and the module may be obscured with or integrated into graphic content in the nature of a printed design on the window. Positioning of the card reader module within the window is not limited to metal or ceramic-coated metal embodiments, however, and may be present in embodiments featuring an all-ceramic or ceramic-coated non-metal body, also.

As shown in <FIG>, the electronics <NUM> and any connecting traces <NUM> may be disposed on a surface of the window, preferably on the back surface of the window where the electronics can be further covered and protected by the backing layer. As shown in <FIG>, in alternate embodiments, electronics <NUM>, <NUM> may be embedded in the window <NUM>, <NUM>. In one embodiment, depicted in <FIG>, embedded electronics may be embedded by injection molding of the electronics <NUM> within a transparent or translucent polymer that comprises window <NUM>. In such an embodiment, one or more conductive members <NUM> connected to the electronics, may be disposed in the window oriented in a direction along the thickness of the window (perpendicular to the front and back faces of the window) so as to transmit electrical power and/or signals from an internal portion of the window to a surface <NUM> of the window (or a layer closer to the surface of the window), where that conductive member <NUM> connects to conductive traces <NUM> printed on the window. Exemplary processes for embedding electronics for insertion in a metal card body are described in <CIT>, titled "TRANSACTION CARD WITH EMBEDDED ELECTRONIC COMPONENTS AND PROCESS FOR MANUFACTURE".

In another embodiment, depicted in <FIG>, the electronics may optionally be disposed on a first layer <NUM> of transparent or translucent polymer, with a second layer <NUM> disposed thereon to envelop the electronics (and optionally, one or more conductive lines <NUM> for connecting to the electronics). A multi-layer window is not limited to only two layers, and may include any number of layers that may provide the aesthetic or functional qualities desired. In a multi-layer embodiment, the conductive lines <NUM> may be printed on a first layer <NUM> before another layer (e.g. <NUM>) is disposed.

Non-metal backing layer <NUM> (e.g. a transparent PVC, but not limited to any particular materials of construction), which is relatively thinner than the relatively thick base, is preferably laminated to the back face of the body and the back face of the window. Although not limited to any particular ranges of thickness, transactions cards are generally standardized in size approximately a thickness of <NUM> inches, and the body is typically in a range of <NUM> to <NUM>, preferably in a range <NUM> to <NUM>, more preferably, <NUM> to <NUM>, with the backing layer optionally having a thickness to make up the difference between the overall thickness and the body, minus the thickness of any adhesive layers or other coatings.

One or more features may be printed on the body, which may comprise a printable metal such as printable stainless steel (e.g. stainless steel having a coating (not shown) at least on front face <NUM> that improves acceptance of printing inks on the steel surface). The coating may comprise, for example, a polyester based coating receptive to UV curable screen and inkjet inks or solvent or oxidation printing. In other embodiments, dye or sublimation printing may be used. For embodiments with a ceramic body, or a ceramic-coated body, the ceramic may be similarly coated, roughened (such as chemically, mechanically, or with a laser), to receive a printed layer. Printed embodiments are not limited to any particular printing technology or technique.

As depicted in <FIG>, the front face of the card may have a decorative pattern. The decorative pattern may be a printed pattern (or may be an engraved or etched pattern, as further explained below), or the front face may be printed with a solid color (e.g. black as shown in <FIG>), or may comprise some combination of solid color, printed graphics or patterns, printed information, and engraved or etched patterns, graphics, or information. Printed information may include the name of the card issuer (e.g. Citi, Bank of America, etc. - represented by the text "BANK" in <FIG>), the type and/or name of the card (e.g. VISA® SAPPHIRE, AMERICAN EXPRESS®), etc. - represented by the text "CARD NAME" in <FIG>), the name of the cardholder, a unique serial number of the card, expiration date, and the like. Certain printed information (e.g. graphics, name of the card) may be printed in a first printing step to create a card "blank" ready for personalization, and other printed information (cardholder, serial number, expiration date) may be printed in a second personalization printing step. The first and second printing steps are typically performed geographically and temporally distant from one another and by different printers. The printing may extend to printing on the window insert, including the printing across the interface between the periphery of the window and the periphery of the hole. The printing may be performed using UV curable inks, but the invention is not limited to any particular type of ink.

The front face of the body may further have decorative grooves disposed therein, such as by etching, machining, lasering, or the like. Thus, in one embodiment, the pattern shown in <FIG> may be composed of a black solid printed base, with grooves disposed in a pattern (depicted as a fish scale pattern in <FIG>, but not limited to any particular type of pattern, and not limited to a repeating or regular pattern, to a single pattern, or to a pattern having any specific amount of coverage - i.e. the pattern(s) may stretch across the entire card face or may be limited to one or more distinct areas of the card). The grooves may be filled, such as with a different color ink than the face of the card, or the grooves may expose the color of the metal or ceramic or body underlying the ceramic beneath the print layer. The grooves may penetrate only the printed layer, or may penetrate the body. The grooves may be cut into the window and extend across the interface between the edge of the body and the window. Similarly, the printed layer on the card may extend across this interface.

Thus, as depicted in <FIG>, the interface <NUM> between the respective peripheries of the window insert <NUM> and the hole <NUM> may be located radially within a printed feature, such as the printed solid black circle <NUM> surrounding the ship graphic <NUM>, such that the printing that extends over the interface helps to visually de-accentuate the interface. In another embodiment, the interface may be located slightly radially outward of circle <NUM>, such that the design imparted by the grooves also extends across the interface, further de-accentuating the interface. In embodiments in which it is desired for the window to be substantially devoid of printing, the printed content may include only the decorative peripheral outline that overlaps the interface (i.e. is disposed on both the window and the card body on either side of the interface), such that the majority of the window located radially inward of the interface or radially inward of the printed peripheral outline is devoid of printing.

In some embodiments, the front face may further comprise an optional hard coat layer <NUM>, whereas other embodiments may have no covering over the printed / engraved layer or over the uncoated metal or ceramic surface on the front face of the card. The transaction card may further comprise a magnetic stripe <NUM>, a signature panel <NUM>, a hologram <NUM>, a machine readable code <NUM> (depicted as a bar code, but may include any type of machine readable code, including but not limited to a QR code), or a combination thereof, preferably disposed over the backing layer <NUM> over the back face <NUM> of the body <NUM>. Most embodiments also include an embedded integrated circuit (not shown) connected to contacts <NUM> configured to be read by a card reader, an embedded RFID antenna (not shown), or a combination thereof (for a dual interface (DI) card), to permit use with contact-based and/or contactless card readers. Although hole <NUM> may be purely aesthetic in nature, the hole may be strategically positioned on the card in a location that enhances RF performance of a dual interface card.

An exemplary process for manufacturing a transaction card as described herein may comprise first providing the body <NUM> having thickness (T), creating hole <NUM> in the body having a periphery and extending from the front face <NUM> to the back face <NUM> of the body. The non-metal backing layer <NUM> is positioned adjacent the back face of the body, preferably tacked in place by an adhesive disposed on the side of the backing layer facing the body, and the non-magnifying transparent insert <NUM> is inserted in the hole <NUM> in contact with the adhesive of the backing layer <NUM>, and the assembly is then laminated together. The insert may be created by any manner known in the art, such as by cutting or punching a plurality of inserts having the desired periphery from a sheet of the insert materials, or by extruding a rod having the periphery of the insert and cutting chips from the rod having thickness (T).

Hole <NUM> may be created by any method known in the art, such as in a metal body by cutting (e.g. mechanical or laser), punching, or etching, such as using computer controlled (e.g. computerized numerical control -- CNC) machines. In an embodiment in which the body comprises printable stainless steel (or any other coated metal in which the integrity of the coating is important), a resist may be applied over the coated surfaces or portions thereof desired to remain coated during any acid etching steps (such as if an etching step is used for creating the hole). For example, the resist is applied to the entire surface of the metal except where hole <NUM> and any other pockets or surface patterns are to be formed. After etching, the remaining resist is removed the body is ready for further processing.

In an exemplary ceramic body embodiment in which the body comprises a solid ceramic, the hole is preferably formed in the green state of the ceramic, and then the ceramic is fired. The size of the pre-firing hole diameter is selected to produce the desired post-filing hole diameter given the characteristics of the ceramic material and expected changes in hole diameter, if any, during the firing process. Although alternative process may involve producing a ceramic blank without a hole, and then mechanically milling, lasering, or freeze/fracturing the hole after firing, such methods are generally less efficient and thus not preferred. In an exemplary embodiment in which the body comprises a metal core with a ceramic coating, the metal body may be created as described above, with the desired ceramic coating then applied over the metal. For example, a spray coating of a ceramic combined with a binder may be applied, or a ceramic may be disposed, such as via injection molding, around the metal, and then fired. In preferred embodiments, the sprayed ceramic coating may be applied only to the front face of the metal core. Ceramic-coated bodies with a non-metal core may be similarly processed.

The laminated assembly may than undergo a printing step, to print the desired matter on the front face of the body. In an exemplary process, the printing step comprises printing the printed matter with an inkjet printer using UV curable ink and then exposing the printing to UV radiation suitable to cure the ink. The front face of the body may be etched or engraved with grooves before or after printing. In a process where the grooves are filled, such as with a different color ink or a metal, a groove-filling step may be performed after grooves are created, such as by a wiping step that wipes filler material across the face so that the filler (ink, metal, resin, etc.) only deposits in the indents created by the grooves.

Although described above in a preferred sequence of steps, it should be understood that the above steps are not limited to performance in any particular sequence. For example, in some processes, the steps of cutting the hole, tacking the backing layer in place, and inserting the window may be performed after steps relating to printing, creating grooves, etc. on the front face of the card. In other processes, the grooves may be created before printing.

As depicted in <FIG>, each finished transaction card <NUM> defines a first bounded area (corresponding to the length and width of the card, minus the area of any rounded edges). In a metal card embodiment, the card may be manufactured from a sheet <NUM> having a second area that is somewhat greater than a multiple of the first area (e.g. slightly greater than 8X as depicted in <FIG>). In such a manufacturing process, the process further comprises cutting the metal sheet into a plurality of transaction cards corresponding to the multiple. As shown in <FIG>, the ratio of the second area to the first area is typically not an integer (e.g. some value between <NUM> and <NUM> as depicted in <FIG>), whereas the multiple corresponding to the number of cards cut from the sheet may represent the closest integer corresponding to the second area, rounded down. The cutting steps for cutting the hole and for cutting the individual cards from the sheet may be performed by a laser. Any grooves may be machined, etched, or laser formed. Although depicted as nearly finished cards in <FIG>, it should be understood that in some embodiments, metal or other material cores may be similarly cut from a larger sheet prior to application of the ceramic coating.

The integrated circuit, and connected contacts and/or antenna, may be embedded in the metal card body by any method known in the art, such as is described in <CIT>. In embodiments where the optional hard coat layer is applied to the front face of the card, the hard coat may be applied as a coating, or as a discrete layer, such as is described in <CIT>. Although described herein with reference to only certain layers, it should be understood that some embodiments may comprise additional layers between, over, or under the described layers, including laminates, adhesive layers, printed content, or coatings (including but not limited to a ceramic coating), without limitation.

Referring now to <FIG>, there is illustrated another transaction card embodiment <NUM>. The transaction card includes a metal layer <NUM> having front and back surfaces and at least two openings <NUM> and <NUM>, each opening extending through one or both of the front and back surfaces of the metal layer. In the embodiment depicted in <FIG>, openings <NUM> and <NUM> both extend through both the top surface and the bottom surface of the metal layer, with opening <NUM> having a relatively greater periphery at the top surface than at the bottom surface. A transponder module <NUM> (preferably contactless or dual-interface) is disposed in opening <NUM>, and may rest on the step <NUM> between relatively wider and relatively narrower portions of opening <NUM>. Transponder module <NUM> may be disposed on or in a plug of non-metal material, as is known in the art.

LED module <NUM> is disposed in opening <NUM>. LED module <NUM> has a planar illuminated area <NUM> visible from a finished surface (e.g. the front surface) of the transaction card. As depicted in <FIG>, in one embodiment LED module <NUM> comprises LEDs <NUM> (depicted as side-fire LEDs) configured to emit light, and a light guide <NUM> for distributing the light emitted by the one or more LEDs across the illuminated area <NUM>. Some portion of the LED module <NUM> may thus be unilluminated. The unilluminated portion may thus be hidden behind opaque areas of an overlying layer or printing on top of the overlying layer, and the features of the overlying layer or printing thereon may be optimized to print across the interface between the periphery of the opening <NUM> and the illuminated portion <NUM> of the LED module. As depicted in <FIG>, the LED module is secured in a window <NUM> that fully penetrates the metal layer from top surface to bottom surface such that a bottom surface of the LED module is flush with the bottom surface of the metal layer and a top surface of the LED module is flush with the top surface of the metal layer. In other embodiments, the LED module may be secured in a blind pocket that does not fully penetrate the metal layer from top surface to the bottom surface. Typically, the LED module, and in particular the illuminated area <NUM>, is non-transparent or non-translucent, such that whatever is disposed behind the LED module (e.g. backing layer <NUM> or the bottom of a blind pocket) is not visible from the front of the card.

Any number of LEDs <NUM> may be provided. In some embodiments, the illumination circuit for the LEDs may include at least two LEDs, with more or different LEDs being illuminated as an indicator of field strength (e.g. greater field strength translates to greater harvested energy and thus greater power available to the illumination circuit, which may illuminate in various power-dependent ways). In some embodiments, all of the LEDs (e.g. 1932a, 1932b) may be the same color, with the circuit configured to illuminate only a first LED at a minimal field strength, and both the first and a second LED at a relatively greater field strength. In circuits with more than two such LEDs (not shown), all of a first, second and third LED may illuminate at relatively greatest field strength. Thus, the energy range for which the first LED illuminates overlaps with the entire energy range of the second LED. In configurations with three LEDs, the energy range over which the first LED illuminates overlaps with the entire energy ranges for which each of the second and third LEDs respectively illuminate, and the energy range over which the second LED illuminates overlaps with the entire energy range over which the third LED illuminates.

In other embodiments, LEDs of multiple colors may be provided, with circuitry configured to illuminate a first LED 1932a (e.g. red) corresponding to a relatively weaker field strength and a second LED 1932b (e.g. green) corresponding to a relatively stronger field strength. The ranges in which the two different LEDs illuminate may have overlapping ranges. For example, a two-LED set may be configured to illuminate red LED 1932a within a first range of power (e.g. <NUM>-<NUM>%) and green LED 1932b within a second range of power (e.g. <NUM>% - <NUM>%), with both LEDs illuminated to produce yellow light within the overlapping range (e.g. <NUM>-<NUM>%).

Intensity of illumination may also be varied based upon strength of field, such that a single LED or multiple LEDs having the same wavelength may provide variation in brightness as a field strength indicator. For example, in embodiments in which both LEDs 1932a and 1932b emit the same wavelength, the intensity of illumination of LED 1932a may range from relatively weaker intensity at <NUM>% field strength to relatively stronger intensity at <NUM>%-<NUM>% field strength, and the intensity of illumination of LED 1932b may range from relatively weaker intensity at <NUM>% to relatively stronger intensity at <NUM>% field strength. Likewise, multiple LEDs having different wavelengths may be illuminated in various combinations of one or more LEDs to create a spectrum of colors based upon strength of field. For example, from relatively weakest to relatively strongest field strength, the LEDs may illuminate in a spectrum (e.g. red = red LED only, optionally over a range of relatively dim to relatively bright intensity; orange = more red LED intensity than green LED intensity; yellow = relatively equal red and green LED intensity; yellow-green = more green LED intensity than red LED intensity; green = green LED only, optionally over a range of relatively dim to relatively bright intensity). The number and/or color of LEDs is not limited to any particular configuration. Those of skill in the field of electronics are familiar with basic circuitry required to illuminate different LEDs in response to power supplied to the circuit, and therefore specific configurations are not detailed herein. Ranges and variations over those ranges are for illustration only, and not intended to limit the invention in any way.

As is understood to those of skill in the art, in use, a contactless or dual-interface transponder module is a component in a transaction circuit configured to communicate with a card reader (not shown) configured to emit radio frequency (RF) waves having energy. As is well known in the art, the transaction circuit includes transponder module <NUM> configured to receive (with receiver connected to antenna <NUM>) an incoming RF signal <NUM> emitted by a transmitting antenna <NUM> of a transmitter in card reader <NUM>, and to respond with an outgoing RF signal <NUM> emitted by a transmitter with transmitting antenna <NUM>, which is received by a receiver with receiving antenna <NUM> of the card reader. Receiver / receiving antenna <NUM> and transmitter / transmitting antenna <NUM> may comprise a single transceiver / transceiver antenna configured for <NUM>-way communications. The transponder is typically powered by harvesting energy from the RF waves <NUM> emitted by the card reader <NUM>. The transponder typically has its own power generation circuit, similar to that described below with respect to the power source for the LED module. In other embodiments, power may be provided by an active-driven RF transceiver with a power source (e.g. a battery) mounted in the device and/or the LED may also have (or share with the transponder) a power source mounted in the device.

LED module <NUM> comprises one or more components in an illumination circuit also powered by energy harvested from RF waves <NUM>. The illumination circuit comprises power source <NUM>, comprising an energy harvesting circuit (configured to produce AC or DC power), LEDs <NUM>, and one or more surface mount technology (SMT) components <NUM>. The illumination circuit, such as in one or more of the SMT components, may include a charge pump (also called a voltage pump or voltage generator), which circuitry is generally known to those skilled in the art, for increasing the operating voltage of the illumination circuit above the voltage of the RF waves. Any type of circuitry for stepping up or stepping down the voltage may be provided. In some embodiments, the illumination circuit and the transaction circuit are isolated from one another such that the illumination circuit is configured to illuminate independent of status of a transaction performed by the transaction circuit. As used herein the term "transaction circuit" refers to any circuit for processing a transaction. In payment devices (credit cards, debit cards), the transaction circuit may comprise a typical payment circuit configured to exchange payment information between the card and the card reader such that the payer's account is ultimately debited, and the payee's account is ultimately credited. Suitable transactions are not limited to payment transactions, however, and may include any exchange of information between the card and the card reader that ultimately results in recording information. For example, a loyalty card for a casino may track the amount a user gambles, wins or loses, which recordation is a "transaction," without the loyalty card actually administering payments associated with the bets, wins, or losses. Thus, to the extent the term "transaction circuit" is used herein, it should be understood to refer to any exchange of information relating to any type of transaction, including but not limited to a payment circuit. In other embodiments, the illumination circuit and the transaction circuit comprise components in a unified circuit in which the illumination circuit is configured to illuminate in a manner indicative of a status of a transaction performed by the transaction circuit. In still other embodiments, both the transaction circuit and the illumination circuit may share power from a single energy harvesting source, without the transaction circuit and the illumination circuit being otherwise connected to one another (i.e. the illumination is not dependent upon status of the transaction).

An exemplary simple energy harvesting circuit <NUM> is schematically depicted in the magnified region of <FIG>, and as is well known in the art, typically comprises a receiving antenna <NUM> for receiving RF waves from a source (in this case waves <NUM> from card reader <NUM>), attached to a rectifier / voltage multiplier <NUM>, a capacitor (or battery) <NUM> in parallel to one or more resistors <NUM> disposed between the antenna <NUM> and ground <NUM>, and produces a direct current (DC) voltage between poles <NUM> and <NUM>. This DC voltage supplies power to the connected circuit(s). Additional components, such as an impedance matching network (IMN) (not shown) between the antenna and the rectifier and/or any other logic or other circuitry components known in the art for use in power harvesting applications may also be included in the circuit <NUM>.

As depicted in <FIG>, metal layer <NUM> has a first discontinuity <NUM> extending from the periphery of the card to opening <NUM> and a second discontinuity <NUM> extending from the periphery of the card to opening <NUM>. Card <NUM> further comprises a back non-metal layer <NUM> disposed on the back surface of the metal layer <NUM>, and a front non-metal layer <NUM> disposed on the front surface of the metal layer. A pattern <NUM>, such as a word, logo, or graphic printed or otherwise disposed on or in the front non-metal layer <NUM>, overlies the illuminated area <NUM> of the LED module positioned to be backlit by the LED module. Although shown as a positive raised pattern <NUM> in <FIG>, such as from printing ink disposed on layer <NUM>, the pattern may comprise opaque portions of non-metal layer <NUM> itself, of a negative pattern formed by holes in an otherwise opaque non-metal layer <NUM>. The pattern may be multicolor. Metal layer <NUM> may act as a booster antenna connected to one of both of antennas <NUM>, <NUM> for boosting the signal received from the card reader, or may be isolated from one or both of the payment and/or illumination circuits.

The location of the opening <NUM> and LED module in close proximity to transponder module <NUM> may provide improved RF performance of the card relative to a card with an absence of the window. Likewise, the first and second discontinuities, <NUM>, <NUM> may also improve RF performance relative to a card with an absence of the discontinuities.

Claim 1:
A transaction card (<NUM>, <NUM>, <NUM>, <NUM>), comprising:
a metal layer (<NUM>) having a visual appearance, a thickness, a metal layer front face (<NUM>, <NUM>, <NUM>), a metal layer back face (<NUM>, <NUM>, <NUM>), and at least two openings (<NUM>, <NUM>) comprising windows (<NUM>) or pockets extending through at least the front face (<NUM>, <NUM>, <NUM>), the metal layer (<NUM>) also including at least one discontinuity (<NUM>) extending from the periphery of the card (<NUM>, <NUM>, <NUM>, <NUM>) to at least one of the at least two openings (<NUM>, <NUM>) and at least one another discontinuity (<NUM>) connected to and extending between the at least two openings (<NUM>, <NUM>);
a transponder module (<NUM>) and an insert (<NUM>, <NUM>, <NUM>, <NUM>) respectively disposed in the one of the at least two openings (<NUM>, <NUM>), such that the insert (<NUM>, <NUM>, <NUM>, <NUM>) is located or positioned in close proximity of the transponder module (<NUM>), the insert (<NUM>, <NUM>, <NUM>, <NUM>) having an insert front-face (<NUM>, <NUM>, <NUM>) visible through the respective one of the at least two openings (<NUM>, <NUM>), the insert front face (<NUM>, <NUM>, <NUM>) having a different visual appearance than the metal layer (<NUM>);
one or more non-functional features visible from a front surface (<NUM>) of the card (<NUM>, <NUM>, <NUM>, <NUM>) in contrast to the visual appearance of the insert (<NUM>, <NUM>, <NUM>, <NUM>) front-facing surface (<NUM>) disposed beneath the non-functional features, wherein the insert (<NUM>, <NUM>, <NUM>, <NUM>) is one of:
(a) non-transparent and non-translucent; or
(b) transparent or translucent, and configured to transmit backlighting to the non-functional features through a back surface (<NUM>) of the card (<NUM>, <NUM>, <NUM>, <NUM>);
the insert (<NUM>, <NUM>, <NUM>, <NUM>) located in the metal layer (<NUM>) in a position that improves RF performance of the transponder module (<NUM>) relative to a card (<NUM>, <NUM>, <NUM>, <NUM>) with an absence of the insert (<NUM>, <NUM>, <NUM>, <NUM>); and
the insert (<NUM>, <NUM>, <NUM>, <NUM>) comprises an illuminable LED (<NUM>, 1932a, 1932b) display, the illuminable LED (<NUM>, 1932a, 1932b) display comprising an OLED module.