The present invention is directed to an integrated electronic substrate a substrate, a radio frequency identification device embedded in the substrate; a metallic deposition disposed on the substrate; the metallic deposition is in electronic communication with the radio frequency identification device to enhance the effective range and power of the radio frequency identification device.

Systems and methods to perform verification of physical control of a security device by a user are disclosed. In one aspect, embodiments of the present disclosure include a method for identifying a symbol in a first image frame of a microlens array of the security device and/or determining a position of the symbol relative to a predetermined point on a 2D plane of the security device. In a further embodiment, a rate of change of the position of the symbol between a second image and the first image frame of the microlens array can be determined. The physical control of the security device by the user is, for example, ascertained if the user is in close proximity to the security device of if the security device is within a line of sight of the user.

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.

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.

RFID-enabled metal transaction cards may include a specially treated thin decorative layer attached to a thick core layer of metal or metal layers (with a discontinuity to function as a coupling frame), or a combination of ceramic and metal separated by a polymeric material, wherein the thin decorative layer is designed to provide selected color(s) and/or selected texture(s) to a surface of the metal core cards. The decorative layer may comprise (a) an anodized metal layer with a discontinuity; or (b) a ceramic layer on a flexible polymeric material. A ceramic-containing transaction card may comprise a monolithic ceramic layer of ultra-thin, flexible zirconia. A PET or PEN layer laminated to the ultra-thin ceramic layer may absorb mechanical stress from flexing or torsion of the ceramic card body.

RFID-enabled metal transaction cards may include a specially treated thin decorative layer attached to a thick core layer of metal or metal layers (with a discontinuity to function as a coupling frame), or a combination of ceramic and metal separated by a polymeric material, wherein the thin decorative layer is designed to provide selected color(s) and/or selected texture(s) to a surface of the metal core cards. The decorative layer may comprise (a) an anodized metal layer with a discontinuity; or (b) a ceramic layer on a flexible polymeric material. A ceramic-containing transaction card may comprise a monolithic ceramic layer of ultra-thin, flexible zirconia. A PET or PEN layer laminated to the ultra-thin ceramic layer may absorb mechanical stress from flexing or torsion of the ceramic card body.

Systems, methods and apparatus are provided for light-based authentication of a payment card. The payment card may include a randomized mix of materials. The materials may include transparent or translucent materials. A light source may shine light on a surface of the payment card. Light passing through the card may generate a light pattern that is unique to the payment card. The light pattern may be captured and compared to a reference light pattern to authenticate the payment card. In some embodiments, photodetectors may detect light patterns generated through interactions with the card materials.

An object marking including a first security element and at least a second security element, wherein each security element is associated with a set of data segments and each security element exhibits depending on the capturing conditions, in particular the viewing angle and/or the direction of illumination, a code segment which is an optoelectronically readable representation of one of the data segments of the set associated with the respective security element, wherein different distinct data segments are represented by different code segments and that the set associated with the first security element and the set associated with the second security element differ in at least one data segment; method for producing and method for authenticating the same.

Systems, methods and apparatus are provided for light-based authentication of a payment card. The payment card may include a randomized mix of materials. The materials may include transparent or translucent materials. A light source may shine light on a surface of the payment card. Light passing through the card may generate a light pattern that is unique to the payment card. The light pattern may be captured and compared to a reference light pattern to authenticate the payment card. In some embodiments, photodetectors may detect light patterns generated through interactions with the card materials.

A transaction card construction and computer-implemented methods for a transaction card are described. The transaction card has vector-formatted visible information applied by a laser machining system. In some embodiments, systems and methods are disclosed for enabling the sourcing of visible information using a scalable vector format The systems and methods may receive a request to add visible information to a transaction card and capture an image of the visible information. The systems and methods may capture data representing the image. The systems and methods may also determine an ambient color saturation of the image. Further, systems and methods may translate the image based on the ambient color saturation of the image. The systems and methods may also map the translated image to a bounding box and convert the mapped image into vector format. In addition, the systems and methods may provide the converted image to a laser machining system.