Abstract: A method for the production of a portable data carrier having an integrated circuit and a contact field galvanically connected to the integrated circuit. In an area defined by the contact field, the portable data carrier is shaped and the contact field is embodied such that a direct contacting of the contact field by a contacting component embodied in accordance with the USB standard is possible. The portable data carrier in its final form is produced in chip card technology. Alternatively, an element is produced in chip card technology, which element features the integrated circuit and the contact filed, and data and/or program code required for the operation of the portable data carrier are loaded into the integrated circuit. Subsequently the element is permanently connected to a carrier.

Abstract: A radio frequency identification (RFID) transponder may include a substrate and a device. The substrate may be in communication with a controller and an antenna, and the antenna is arranged to receive radio frequency signals. A first side surface of the substrate may include a capacitor. The device may be detachably coupled with the substrate via a conductive member positioned between the structure and the capacitor of the substrate, and the conductive member may be within a desired proximity of the capacitor. The structure may be attached to an attachment surface so that an attachment strength between the structure and the attachment surface may be greater than a force required to decouple the structure from the substrate. When the structure is decoupled from the substrate, the conductive member separates from the capacitor, disabling the transponder.

Abstract: An element which has a decorative outer surface comprising: a first region having a constant luminance that is equal to a first predetermined value; and one second region adjacent to the first region, wherein the second region has a variable luminance that depends on the viewing angle, the variable luminance of the second region being equal to the first predetermined value for a first given viewing angle.

Abstract: An electronic component may include an integrated circuit device package and a second substrate. The integrated circuit device package may include a first substrate being bent or spread, a heat transfer member disposed in the first substrate, an integrated circuit device being bent or spread, a first pad disposed on one face of the integrated circuit device, and an adhesion member disposed between the integrated circuit device and the first substrate. The second substrate may be bent or spread. The second substrate may include a second pad. The integrated circuit device package may be combined with the second substrate by a thermo compression bonding process in which the heat transfer member may transfer a heat to the second substrate through the first substrate and the first pad may make contact with the second pad.

Abstract: A card, comprises an electrically non-conductive substrate; a first predetermined pattern of electrically conductive material applied on said electrically non-conductive substrate; and an electrically non-conductive covering layer applied on said electrically conductive material arranged on said substrate such that said first predetermined pattern of electrically conductive material is covered; said card further comprises a second predetermined pattern in a predetermined grey percentage applied on said electrically non-conductive substrate, said predetermined second pattern being the negative of said first predetermined pattern, and said electrically non-conductive covering layer is also applied on said second predetermined pattern such that said second predetermined pattern is covered, and the greyness of said second predetermined pattern has been determined such that the colour of the electrically non-conductive covering layer is uniform.

Abstract: A security chip against counterfeiting, especially for banknotes and other documents (e.g. pre-numbered forms), enabling the verification of the authenticity of a document.

Abstract: A smart card comprising: a memory for storing information; at least one transmitting or receiving antenna; and a low frequency circuit, for handling information associated with said antenna and said memory, which information is modulated at a modulation frequency of between 5 kHz and 100 kHz. Preferably the antenna is an acoustic antenna.

Abstract: A smart card with two read-write modes includes antenna layer, and an antenna and a chip module circuits on the antenna layer, wherein the antenna and the chip module circuit are electrically connected via an elastic conductive device. The invention also provides a manufacturing method of the aforesaid smart card with two read-write modes, which includes steps of: embedding an antenna on a back side or a front side of an antenna layer; after completing embedding on the antenna layer, add bedding sheets, printed sheets and protection films respectively above and underneath the antenna layer, then laminating to obtain a card base carrier; cutting card from the treated whole-sheet card base carrier to obtain a card base, and milling slots on the obtained card base, then finally encapsulating.

Abstract: An embedded electronic device and a method for manufacturing the same wherein the embedded electronic device is composed of a printed circuit board, having a top surface and a bottom surface, a plurality of circuit components attached to the top surface of the printed circuit board having a plurality of standoffs on the bottom surface of the printed circuit board, a bottom overlay attached to the bottom surface of the printed circuit board, a top overlay positioned above the top surface of the printed circuit board and a core layer positioned between the top surface of the printed circuit board and the top overlay.

Abstract: The invention relates to a luminescent composition comprising a component which can be excited by infrared (IR) radiation and a component which can be excited by ultraviolet (UV) radiation. The composition has a characteristic emission spectrum and may optionally be used together with a reading system adapted to the emission spectrum in order to mark substances or mixtures of substances.

Abstract: It is an object to provide a highly reliable display device. It is a feature an IC is over a substrate and a material layer having the same height is thereover. An IC is provided on one side of the substrate, and a material layer having the same height as the IC is provided on at least another side. Further, an IC is provided on one side of the substrate, and material layers having the same height as the IC are provided on the other sides. Further, an IC is provided on one side of the substrate, and a material layer having the same height as the IC is provided at a corner of the substrate.

Abstract: According to an embodiment, there is provided a label printer including a conveying mechanism, an RFID reader and writer, a communication intensity information acquisition unit, and a maximum communication intensity position determination unit, and an optimal communication position calculation unit. If communication with the plurality of RFID tags occurs simultaneously in the RFID reader and writer while conveying the mount by the conveying mechanism along the conveying route, the communication intensity information acquisition unit acquires information indicating a communication intensity between each of a plurality of the RFID tags and the RFID reader and writer in correlation with identification information of each of the RFID tags.

Abstract: A proxy card for persistently emulating a set of magnetic stripe data associated with a payment card is disclosed. The proxy card provides a magnetic stripe emulator that includes a plurality of parallel traces of conductive material oriented in a direction perpendicular to a direction in which the proxy payment card is designed to be swiped. The parallel traces are coated with a layer of a magnetic medium of low coercivity. A microcontroller on the proxy card generates electrical signals to drive electrical current along each of the plurality of parallel traces in a selected direction. The electrical current causes alignment of particles in the magnetic medium of the magnetic stripe emulator which encodes the set of magnetic stripe data on the magnetic stripe emulator. The proxy card can then emulate the payment card when swiped through a magnetic card reader without consuming any power.

Abstract: Weighted transaction cards and methods of manufacturing the same. The weighted transaction cards may include a tungsten member that comprises at least a portion of a layer of the transaction card. The tungsten member may be encapsulated and/or disposed in an opening of a surround to define and inlay. The inlay may be laminated with one or more additional layers according to traditional card manufacturing techniques (e.g., a hot lamination process). The weighted transaction cards may have a weight significantly greater than traditional plastic transaction cards such that the weighted transaction cards.

Abstract: Provided is a metal card including a metal card sheet made of duralumin and an anodized layer formed by anodizing a surface of the metal card sheet, wherein a background color or pattern of the metal card is determined according to a composition of electrolyte of the anodizing for forming the anodized layer.

Abstract: A wearable tag capable of wireless communications includes a first elastic layer, a second elastic layer over the first elastic layer, wherein the second elastic layer is embedded with a first conductive circuit. The wearable tag includes a dielectric layer on the second elastic layer, a third elastic layer on the dielectric layer, wherein the third elastic layer is embedded with a second conductive circuit, wherein the dielectric layer comprises via holes that contain electric connections between the semiconductor chip and the first conductive circuit. A semiconductor chip is in connection with the first conductive circuit and the second conductive circuit, wherein the semiconductor chip, the first conductive circuit, and the second conductive circuit are configured to wirelessly communicate with external devices. The wearable tag also includes a fourth elastic layer on the semiconductor chip.

Abstract: The claimed subject matter provides a system and/or a method that facilitates servicing a portion of a trade card via a web service. A web service can provide a portion of data to enhance a trade card, wherein the portion of data is at least one of a portion of trade card document-specific data, an intelligent gadget, or a feed driven component. A build component can leverage the web service to utilize the portion of data with the trade card.

Abstract: In a smart card having an antenna structure and a metal layer, an insulator layer is formed between the antenna structure and the metal layer to compensate for the attenuation due to the metal layer. The thickness of the insulator layer affects the capacitive coupling between the antenna structure and the metal layer and is selected to have a value which optimizes the transmission/reception of signals between the card and a card reader.

Abstract: A device is described for the hiding and subsequent recovery of visual information. The device comprises two or more tokens (1), each containing a mask (2,3) of coloured pixels (4), are overlaid (5), so that when the pixels are aligned, hidden information, invisible in the individual tokens. The hidden information consists of one or more recognisable alphabetic, numerical or pictorial characters (6). During token overlay and alignment, the information becomes recognisable because it is made up of pixels whose colour is differentiated from the other pixels in the overlay. The information is hidden by adding pixels of certain colours. When the tokens are overlaid and the pixels aligned, the added pixels are effectively subtracted, revealing the hidden information. The tokens may be printed on various media, or may be displayed on an electronic device.

Abstract: A radio frequency identification tag comprises a chip; a circuit antenna connected to the chip; and a substrate having a front side carrying the chip and the circuit antenna and formed with a scribing portion, wherein the scribing portion overlaps at least one part of the circuit antenna when viewed from a back side of the substrate.

Abstract: The disclosure prevents, with improved reliability, an IC tag from being broken, while ensuring overall flexibility of the IC tag. The IC tag 100 is provided with a covering 140 made of an elastic material, which covers at least the side of the IC tag 100 on which an IC chip 130 is mounted and has a thickness that is larger in its portion 140a that covers a region about the IC chip 130 than in its portion 140b that covers a region outside the region about the IC chip 130. The covering 140 is configured in such a way that at least a part of a boundary of the portion 140a of the covering that covers the region about the IC chip 130 and the portion 140b of the covering that covers the region outside the region about the IC chip 130 has a curved shape.

Abstract: A Non-transferable Radio Frequency Identification (RFID) assembly for attachment to an article comprises a RFID module; and a antenna module coupled with the RFID module, the antenna module comprising a conductive layer, a substrate, and an adhesive modification layer between the conductive layer and the substrate, the adhesive modification layer configured such that when the assembly is attached to the article and attempt to remove the assembly will cause the substrate to release and leave the conductive layer intact.

Abstract: The invention relates to a transponder layer (10), in particular for producing a chip card, having an antenna substrate (12), which, on an antenna side (11), is equipped with an antenna (14) formed from a wire conductor (13), and has a chip accommodation which is formed by a recess in the antenna substrate and in which a chip (21) is accommodated, wherein wire conductor ends, which serve to form terminal ends (15) of the antenna, are formed at a bottom (20) of the chip accommodation which is recessed with respect to the rear side (26) of the antenna substrate (12), and the chip is accommodated in the chip accommodation in such a manner that terminal contacts (22) arranged on a contact side (36) of the chip are contacted with flat contact portions (19) of the terminal ends (15), and the chip is arranged with the rear side (27) of its semiconductor body (28) facing the terminal contacts substantially flush with the rear side of the antenna substrate.

Abstract: A metal transaction card is provided having a metal core layer with metal cladding layers connected thereto on opposing sides thereof. The metal core layer may have a density and/or thickness that is significantly greater than the density and/or thickness of the metal cladding layers. The density of the metal core layer may be at least 2.5 times greater than the density of the metal cladding layers. The density of the metal core layer may be at least 7.5. The outward facing lateral surface of one or both of the metal cladding layers may be anodized, or anodized and colorized. The anodized lateral surface(s) may be coated to increase the performance of a one or more hot-stamped elements attached to the coated surface(s).

Abstract: High density metal or mineral particles, sized to be less than 10 microns, are compounded into a base plastic layer to form a compounded composite layer used to form the core layer of the card, any layer of the card or the entire card. The amount of high density particles compounded into the plastic layer is controlled so the card: (a) is at least twice as heavy as any standard PVC card; (b) can be manufactured using standard current plastic card equipment and tooling. (c) is not brittle; and (d) is electrically non-conductive whereby it is not subject to electrostatic discharge properties. The card can include RFID functionality integrated into the card body. The compounded composite layer does not interfere with the integrity of the data communication between an RFID chip packaged in an antenna module and coupled with an embedded booster antenna, and a contactless reader or terminal.

Abstract: Wireless devices such as sensors, interactive displays and electronic article surveillance (EAS) and/or radio frequency identification (RFID) tags including integrated circuitry and an antenna and/or inductor printed thereon, and methods for making and using the same, are disclosed. The device generally includes an integrated circuit on a substrate and an antenna, directly on the substrate and/or the integrated circuit, in electrical communication with the integrated circuit. The method of making a wireless device generally includes forming an integrated circuit on the substrate and printing at least part of an antenna or antenna precursor layer on the integrated circuit and/or substrate. The present invention advantageously provides a low cost wireless device capable of operating at MHz frequencies that can be manufactured in a shorter time period than conventional devices.

Abstract: An RF tag includes an inlay comprising an IC chip and an antenna, a planar auxiliary antenna laminated on the inlay in an insulating state to the inlay, and a substrate on which the inlay and the auxiliary antenna are laminated. The auxiliary antenna is formed into a rectangular planar shape including long sides each having a length of substantially ¼ of a wavelength of a radio wave frequency of the inlay, and has a cutout part which divides one of the long sides into two parts each having a length of substantially ? of the wavelength of the radio wave frequency of the inlay. The cutout part is formed into a concave shape which is opened in an edge portion of the one of the long sides and has a predetermined width and depth to allow the IC chip of the inlay to be disposed therein.

Abstract: An RF tag has an inlay with an IC chip and an antenna, a planar auxiliary antenna laminated on the inlay in an insulating state, a dielectric constant regulation plate which becomes a base on which the inlay including the auxiliary antenna laminated thereon is mounted, and functions as a dielectric constant regulation layer for the mounted inlay, and a case which receives the dielectric constant regulation plate in a state where the inlay including the auxiliary antenna laminated thereon is mounted. The dielectric constant regulation plate is formed into a shape which allows the dielectric constant regulation plate to be attachably/detachably and non-movably engaged in the case and which allows the dielectric constant regulation plate to have a predetermined dielectric constant which regulates communication characteristics of the inlay including the auxiliary antenna laminated thereon.

Abstract: A flexible card may include a dynamic magnetic stripe communications device having multiple layers, such as an electromagnetic generator, a magnet, and a shield. A shield may form a non-flexible layer within the stack and may bend, but the shield may not be able to stretch or compress. Flexible layers may surround and adhere to the shield such that when the card is flexed, the flexible layers may stretch and compress with the movement of the shield. The dynamic magnetic stripe communications device may include one or more coils. Each coil may contain a stepped material, such that a length of a lower layer of the stepped material is longer than a length of a middle layer of the stepped material which is longer than a length of a top layer of the stepped material.

Abstract: A secure transaction card does not interact with an interrogating radio frequency field without user interaction. The user interaction may include pressing on the card to cause a smartcard chip to connect to a coil on the card. The user interaction may also include exposing the card to light, motion, touch, or the like. Control of the secure transaction card may be active or passive.

Abstract: An ID document includes a document core and a multi-layer laminate. The multi-layer laminate includes at least three layers: a top layer, a middle layer, and a bottom layer. The top layer, in combination with other layers, provides durability to the ID document. The top layer can be made of a material with strong intrusion or scratch resistance and a high thermal softening/deformation point and can also have high resistance to solvents. The middle layer may be made of a material with a low melting point, and may also have high resistance to solvents. The bottom layer helps to facilitate strong binding to the document core or inlay and may be made of a material with a relatively high melting point.

Abstract: A product authentication label includes a carrier layer made of a transparent or translucent material, a plurality of first reflection pattern forming bodies disposed in the carrier layer and configured to reflect a substantially identical reflection pattern regardless of the direction of irradiated light, and a plurality of second reflection pattern forming bodies randomly disposed in the carrier layer and configured to reflect a reflection pattern which varies depending on the direction of irradiated light.

Abstract: A breakaway RFID tag is configured such that it comprises part of a Printed Circuit Board Assembly (PCB). Thus, the breakaway RFID tag can be used to track the PCB as it migrates through a manufacturing process. In one embodiment, the RFID tag can be assembled first and then used to track the PCB as it is populated with components and installed into larger assemblies and ultimately into the end device. Once the PCB is installed into a larger assembly or the end device, the breakaway RFID tag is configured such that it can be broken off and attached to the outside of the larger assembly or end device.

Abstract: A laminar assembly including a first optically opaque layer defining a plurality of through-holes, a second optically opaque layer, an optically transparent inner layer between the inner surface of the first optically opaque layer and the inner surface of the second optically opaque layer, and a preprinted layer proximate the outer surface of at least one of the first and second optically opaque layers. The plurality of through-holes is at least partially filled with material from the optically transparent inner layer, and light is visibly transmitted in a single direction through the plurality of through-holes. Unidirectional opacity watermarks defined by the plurality of through-holes in the laminar assembly provide advantageous anti-counterfeiting measures, and are easy to view and authenticate, yet difficult to simulate.

Abstract: This invention relates to a transparent or translucent transaction card having a base comprising a core of substantially transparent or translucent material with a plurality of coats, including optically recognizable ink comprising one or more infrared blocking dyes and other nanoparticles, such as rare earth nanophosphors and other metal nanoparticles, and/or optically recognizable film comprising nanoparticles, such as rare earth nanophosphors, and other metal oxide and/or non-oxide complexes, and methods for their preparation.

Abstract: Systems and methods for integrating radio-frequency identification (RFID) circuitry into flexible circuits are provided. An RFID integrated circuit can be embedded within a dielectric layer of a flexible circuit or between a dielectric layer and a conductive layer of the flexible circuit. Additionally or alternatively, an RFID antenna may be integrated into a conductive layer of the flexible circuit. Alternatively, both the integrated circuit and antenna of RFID circuitry may be provided off of the flexible circuit but an RFID connector coupling the integrated circuit and antenna may be integrated into the flexible circuit.

Abstract: A multilayer contactless smartcard 10 including an electronic chip embedded in the card, the chip being connected to an antenna 22 printed on a carrier layer 20, and two card bodies, one on each side of the carrier, each including at least one plastic layer 40 and 60. The antenna carrier is opaque and includes a first cut-out forming a void 23 filled with a transparent plastic; and the plastic layers of the two card bodies each include a second cut-out forming two identical voids 43 and 63 the outlines of which superimpose, in order to make a transparent zone appear in the thickness of the card, forming a transparent logo in the shape of the cut-out. A process for manufacturing such a card is also disclosed.

Abstract: A method for producing a smart card module arrangement includes: arranging a smart card module on a first carrier layer, wherein the first carrier layer is free of a prefabricated smart card module receptacle cutout for receiving the smart card module. The smart card module includes: a substrate; a chip on the substrate; a first mechanical reinforcement structure between the chip and the substrate. The first mechanical reinforcement structure covers at least one part of a surface of the chip. The method further includes applying a second carrier layer to the smart card module, wherein the second carrier layer is free of a prefabricated smart card module receptacle cutout for receiving the smart card module; and at least one of laminating or pressing the first carrier layer with the second carrier layer, such that the smart card module is enclosed by the first carrier layer and the second carrier layer.

Abstract: A method of preparing a security laminate including the steps of: a) providing a polyethylene terephthalate substrate (1); b) stretching the polyethylene terephthalate substrate in either a longitudinal or a transversal direction; c) coating and drying a first coating composition (2) on the stretched polyethylene terephthalate substrate; d) stretching the coated polyethylene terephthalate substrate in the longitudinal or transversal direction not selected in step b) in order to obtain a coated biaxially stretched polyethylene terephthalate substrate having a layer of the first coating composition with a dry thickness between 50 nm and 400 nm; e) coating and drying a second coating composition (3) on top of the dry layer on the biaxially stretched substrate, wherein the first coating composition contains a copolymer selected from the group consisting of a hydroxyl—functional, partially-hydrolyzed vinyl chloride/vinyl acetate copolymer and a polyester-urethane copolymer; and wherein the second coating compositi

Abstract: An RFID tag substrate on which an RFID tag that performs wireless communication with a reader/writer is disposed includes a substrate layer, and a functional layer laminated or stacked on the substrate layer. The functional layer includes a plurality of layers laminated together including a high-dielectric-constant layer having a predetermined dielectric constant, and a high-permeability layer having a predetermined permeability. A product of the predetermined dielectric constant and the predetermined permeability is not smaller than 250.

Abstract: An RFID tag includes: a base sheet in which a plurality of first slits are formed to extend alternately from two opposite sides from an end of the base sheet; an antenna pattern provided on the base sheet by folding the antennal pattern to avoid the first slits; an RFID chip provided over the base sheet and electrically connected to the antenna pattern; an elastic sheet provided over any one of a top surface and a bottom surface of the base sheet; and a protective sheet provided on a surface of the elastic sheet opposite to the surface that is in contact with the base sheet and including second slits formed to correspond in position to the first slits of the base sheet.

Abstract: A standoff RFID element includes a generally planar, hollow, standoff member with a pair of major outer walls connected by a plurality of structural components like ribs and at least a first piece of flexible, planar, non-conductive polymer substrate having one major side bonded with a major side of the standoff member. An RFID inlay is encapsulated between the hollow member and the piece of polymer substrate. The hollow member is formed from a non-conductive, non-porous, polymer material. The flexible substrate is non-conductive and substantially porous.

Abstract: An RFID tag including an inlay having a sheet-like shape and including an antenna and an IC chip electrically connected to the antenna, an outer covering member that covers the inlay, the outer covering member having a planar shape and including a main surface and a rear surface, and a frame part arranged on at least one of the main surface and the rear surface. The frame part is erected in a thickness direction of the outer covering member. The frame part surrounds the IC chip in a plan view.

Abstract: A self adhesive type radio frequency anti-counterfeiting and anti-reclamation label includes a self-adhesive label provided with characters or patterns and has its inner surface formed with a gluing layer. A radio frequency identification system is installed at the outer side of the gluing layer and provided with a foundation plate mounted with a radio frequency chip and an antenna serving as a passive source signals sent out by the identification chip. A tearing region is formed between the label and the radio frequency identification system for receiving therein the radio frequency identification system, the antenna or the identification chip. The label can be torn up, or the tearing region can be torn off manually to separate the label from the radio frequency identification system, or separate the identification chip from the antenna, letting the original label impossible to be recycled for attaining an objective of anti-counterfeiting.

Abstract: In one aspect, a device for identifying a subject includes a tattoo layer and a removable cover. The tattoo layer is attachable onto the subject to form a temporary tattoo, and is formed with a resistant material being adhesive such that the temporary tattoo adheres onto the subject. The removable cover detachably covers the tattoo layer. To generate the device, a user may use a computer system to operate a management software to generate the visualization codes including the identification information of the subject, and to print the visualization codes with the resistant material as the tattoo layer on the removable cover. The tattoo layer includes visualization codes thereon, and the visualization codes include identification information of the subject. The user may use a scanner to scan the visualization codes of the tattoo layer to obtain the identification information of the subject, thus identifying the subject.

Abstract: Systems and methods for identifying, tracking, tracing and determining the authenticity of a good are described herein. In some embodiments, a system includes an imaging system, a database, and an authentication center. The imaging system is configured to capture an image of a unique signature associated with a good at the good's origin. The unique signature can be, for example, a random structure or pattern unique to the particular good. The imaging system is configured to process the image of the good to identify at least one metric that distinguishes the unique signature from unique signatures of other goods. The database is configured to receive information related to the good and its unique signature from the imaging system, and is configured to store the information therein.

Abstract: A method for producing a card-shaped data carrier directly in the ID-000 format (plug-in), and for combining the production method with the incorporation of security features, individualization data and personalization data. In so doing, a card body having ID-000 dimensions is connected directly to the rear side of a film carrier or module tape, being for example cast or injection-molded thereonto. The film carrier is preferably transparent or semitransparent. Through the film carrier the card body can be marked and inscribed by means of laser radiation.

Abstract: A carrier element with a QR code, including a decorative area having a decorative design with an inner area (1) with the QR code and an outer area (2) that is adjacent to the inner area (1) or at least partially surrounds the inner area. The decorative design has, in the outer area (2), an outer design with pattern sections that are combined from elements of QR codes.

Abstract: A method for manufacturing a multilayer card body for a portable data carrier includes the steps of: making available two layers of synthetic paper, making available at least one cover layer of plastic, printing the upper side of the layers of synthetic paper with a graphical pattern by a screen printing or offset printing process, bringing together the layers into a half-product, laminating the layers together under conditions typical of chip cards, separating the card body from the half-product by means of a separating tool.

Abstract: A card, such as a payment card, or other device may include an electronics package. The electronics package may include electronic components mounted on a flexible, printed circuit board. The electronics package may be laminated (e.g., via a hot, cold, or molding lamination process) between layers of transparent polymer. A hologram may be fixed to one side of the electronics package such that the hologram may be viewed from the exterior of the laminated card having transparent polymer layers. As such, the hologram may not be removed without breaching the integrity of a transparent polymer layer.