The invention is related to a layered structure with at least one layer a. of a material with a VST≥85° C. comprising at least one cutting line b. reaching through the whole thickness of the layered structure surrounding at least one first portion which is extractable and reinsertable manually from the layered structure as well as a production process for such a layered structure.

A game token by which a plurality of RFID tags embedded in a plurality of the game tokens stacked each other can be read in a relatively stable manner is provided. A game token is provided with a security part and a receiving part that receives the security part. The security part has a shape with a diameter smaller than the diameter of the receiving part, a structure with a plurality of plastic layers laminated together, an RFID tag, and a visible print layer indicating a type or ID of the game token. The receiving part has a surface. The surface of the receiving part has a recessed portion for receiving the security part, and the depth of the recessed portion is 25% or more of the thickness of the game token.

A transaction card having a front “continuous” (with no slit) metal layer (530, 630, 730) with an opening (506, 612, 712) for a dual-interface transponder chip module (510, 610, 710). A shielding layer (540, 640, 742) comprising ferrite material (shielding layer) disposed below the metal layer. An amplifying element (507, 650, 744) disposed under the shielding layer. A metal interlayer (750, FIG. 7B) with a slit to function as a coupling frame (CF). A coupling frame antenna (507) having a single turn or track mounted on a supporting substrate (502). A rear plastic layer (560, 660, 760) formed of non-RF impeding material may capture a magnetic stripe and security elements (signature panel and hologram). The coupling frame antenna (507) may be integrated into the rear plastic layer. A portion of the front metal layer may protrude downward into the shielding layer. A dielectric spacer (548, 648, 748) may be disposed between the shielding layer and the amplifying element. A compound-filled recess for embedding an electronic component is also disclosed.

A game token by which a plurality of RFID tags embedded in a plurality of the game tokens stacked each other can be read in a relatively stable manner is provided. A game token is provided with a security part and a receiving part that receives the security part. The security part has a shape with a diameter smaller than the diameter of the receiving part, a structure with a plurality of plastic layers laminated together, an RFID tag, and a visible print layer indicating a type or ID of the game token. The receiving part has a surface The surface of the receiving part has a recessed portion for receiving the security, and the depth of the recessed portion is 25% or more of the thickness of the game token.

A system for prevention of electrostatic discharge from a payment card to a point of sale (POS) device comprising an integrated circuit card (ICC) socket, includes a spring member comprising a first end electrically coupled to a second end. The first end is electrically coupled to an electrical ground, the first end is mechanically coupled to the POS device, and the second end is positioned for contact with a top edge of the payment card. When the payment card is inserted into the ICC socket and the top edge comes into contact with the second end, the first end and the second end form a first electrical path for electrostatic discharge between the payment card and the electrical ground.

A transaction card, and processes for the manufacture thereof, having a core layer, optionally, one or more layers or coatings over the core layer, and at least one of a magnetic stripe, a machine readable code, and a payment module chip disposed in or on the card and suitable for rendering the card operable for conducting a transaction. The core layer comprises a metal-doped cured epoxy comprised of metal particles distributed in a binder consisting essentially of a cured, polymerized epoxy resin, the core comprising greater than 50%, preferably greater than 75%, and more preferably greater than 90%, of the weight and/or volume of the card. In some embodiments, the core includes a metal insert enveloped with the metal-doped curable epoxy, wherein the periphery of the epoxy extends beyond the periphery of the metal insert and has material properties more conducive to cutting or punching than the metal insert.

A package for an integrated circuit is marked with an encoded image (e.g., a two-dimensional barcode). The encoded image is scanned by a scanner to obtain manufacturing parameters. In one approach, a method includes: fabricating, in a manufacturing facility, a physical product using a manufacturing process, where the physical product is fabricated according to specifications, and the manufacturing process includes manufacturing steps performed in the manufacturing facility; marking the physical product with an encoded image, where the encoded image encodes parameters that include the specifications; and transporting the physical product to a storage facility, where the storage facility includes a scanner configured to scan the encoded image to obtain the parameters.

A holder for cards providing RFID protection is disclosed herein. The holder comprises multiple sheaths, where each sheath has a card position adjacent a protective assembly and a means for holding the card adjacent the protective assembly. Each protective assembly comprises a conductive layer and an absorbing layer adjacent the card position. The sheaths are hingedly connected to enable the user to select a single card for desired use without the need to remove the card from the holder. Once the desired card read has been completed, the cards within the holder are shielded from unauthorized or malicious card reads.

Cards embodying the invention include a core subassembly whose elements define the functionality of the card and a hard coat subassembly attached to the top and/or bottom sides of the core subassembly to protect the core subassembly from wear and tear and being scratched. The core subassembly may be formed solely of plastic layers or of different combinations of plastic and metal layers and may include all the elements of a smart card enabling contactless RF communication and/or direct contact communication. The hard coat subassembly includes a hard coat layer, which typically includes nanoparticles, and a buffer or primer layer formed so as to be attached between the hard coat layer and the core subassembly for enabling the lasering of the core subassembly without negatively impacting the hard coat layer and/or for imparting color to the card.

A portable item reporting device (200) is configured to be attached to and in substantial collocation with a portable item (100), or to be integrated into a portable item (100). The device (200) includes environmental sensors (210) to monitor item location, movement, ambient light, sounds, temperature, etc. The device (200) is configured to store usage expectation data (600) indicative of historical and/or expected item usage and environments when the item (100) is in normal use/storage associated with an authorized user (AU). The device (200) monitors current environmental conditions (104) surrounding and pertaining to the item. If the current environment (104) is inconsistent with expected conditions (600), the device (200) assesses that the item (100) is displaced (503.0), meaning either that the item (100) is in abnormal use or abnormal storage, or is under the control of an unauthorized user (UU) who is other than the authorized user (AU). Based on the assessment the device initiates a signal (372) or message (374) to an authorized user (AU) of the item (100), indicating that the item (100) usage/storage is displaced (503.0) or otherwise anomalous (503.2).