Electrical circuit for a smart card chip module, including an insulating layer having a front main face and a rear main face. An antenna is made in a first conductive layer laying on the rear main face. This antenna extends over an antenna area delimited by a peripheral edge. The antenna includes at least one inner loop and one outer loop. The outer loop runs along the peripheral edge except over at least one first connecting segment diverted from the peripheral edge, towards or in a central zone of the antenna area. Further, the outer loop of the antenna includes at least a second connecting segment diverted from the peripheral edge towards a central zone of the antenna area.

Dispensing devices and systems for oral transmucosal administration of small volume drug dosage forms to the oral mucosa are provided. The dispensing device may be a single dose applicator (SDA), or an electromechanical device comprising a means for patient identification such as a wrist worn RFID tag and annular bidirectional antenna together with a lock-out feature.

RFID devices comprising (i) a transponder chip module (TCM) having an RFIC chip (IC) and a module antenna (MA), and (ii) a coupling frame (CF) having an electrical discontinuity comprising a slit (S) or non-conductive stripe (NCS). The coupling frame may be disposed closely adjacent the transponder chip module so that the slit overlaps the module antenna. The RFID device may be a payment object such as a jewelry item having a metal component modified with a slit (S) to function as a coupling frame. The coupling frame may be moved (such as rotated) to position the slit to selectively overlap the module antennas (MA) of one or more transponder chip modules (TCM-1, TCM-2) disposed in the payment object, thereby selectively enhancing (including enabling) contactless communication between a given transponder chip module in the payment object and another RFID device such as an external contactless reader. The coupling frame may be tubular. A card body construction for a metal smart card is disclosed.

Ingestible radio frequency identification (RFID) tags are disclosed. A system embodiment includes, but is not limited to, an RFID tag including a flexible substrate foldable between a planar configuration and a tubular configuration, a conductive element disposed on the flexible substrate, and an RFID tag chip electrically coupled with the conductive element; a capsule structured and dimensioned for ingestion by a biological subject, the capsule including a shell structured and dimensioned to enclose a medication for the biological subject simultaneously with the RFID tag when the flexible substrate is in the tubular configuration, but not when the flexible substrate is in the planar configuration; and a pH switch structure coupled to an exterior surface of the capsule, the pH switch configured to deactivate the RFID tag in a first configuration and to permit activation of the RFID tag in a second configuration within the biological subject.

A multilayer stack includes a first stretchable layer having a first length, a first adhesive layer disposed on a top surface of the first stretchable layer and having the first length, a second stretchable layer disposed on a top surface of the first adhesive layer and having a second length smaller than the first length, a radio frequency identification tag including an antenna having a spiral form and disposed on a top surface of the second stretchable layer or on a bottom surface of the second stretchable layer, a second adhesive layer disposed on the second stretchable layer and having a third length less than the first length and greater than the second length where the second adhesive layer encapsulates the second stretchable layer, and a third stretchable layer disposed on a top surface of the second adhesive layer and having the third length.

An RFIC module is provided that includes an RFIC and an impedance matching circuit connected to an RFIC side first terminal electrode, an RFIC side second terminal electrode, an antenna side first terminal electrode and an antenna side second terminal electrode. The impedance matching circuit includes a first inductor, a second inductor, a third inductor, and a fourth inductor, and a conductor pattern that configures the first inductor, the second inductor, the third inductor, and the fourth inductor as a single coil-shaped pattern.

The present disclosure relates to a smart card device comprising: a laminated core comprising: a front substrate (10); a first flexible sheet (20) having a card circuitry formed thereon; a first substrate (30); a second flexible sheet (40) having an inductive circuitry formed thereon, and a second substrate (50) in a top-to-bottom order, wherein the front substrate (10) provides at least one first opening (11) which defines a perforated design and a second opening (12) through which a contact pad (22) is exposed, wherein the card circuitry includes: a flip chip (21), a first antenna coil (24) conductively coupled to the flip chip (21), the contact pad (22), at least one conductor path (23) conductively coupling the contact pad (22) to the flip chip (21), wherein the inductive circuitry includes at least one LED module (46) arranged proximate to the at least one first opening (11) and a second antenna coil (44) conductively coupled to the at least one LED module (46), and wherein the first substrate (30) includes at least one light guide (31) which is arranged under the at least one first opening (11) and configured to direct an illumination produced by the at least one LED module (46) through the at least one first opening (11) to illuminate the perforated design.

A transaction card can be manufactured from rigid materials, such as glass, stone, or ceramics. The transaction card can have a first rigid layer having a first external surface and a first internal surface, with a pocket within the first external surface of the first rigid layer. The transaction card can have a second rigid layer having a second external surface and a second internal surface. A binding layer can be located between the first rigid layer and the second rigid layer can affix the first rigid layer to the second internal layer. An integrated circuit chip can be affixed within the pocket of the first rigid layer. A rim can extend from the first external surface of first rigid layer around a first edge of the first rigid layer and a second edge of the second rigid layer and onto the second external surface of the second rigid layer.

Smartcards with metal layers manufactured according to various techniques disclosed herein. One or more metal layers of a smartcard stackup may be provided with slits overlapping at least a portion of a module antenna in an associated transponder chip module disposed in the smartcard so that the metal layer functions as a coupling frame. One or more metal layers may be pre-laminated with plastic layers to form a metal core or clad subassembly for a smartcard, and outer printed and/or overlay plastic layers may be laminated to the front and/or back of the metal core. Front and back overlays may be provided. Various constructions of and manufacturing techniques (including temperature, time, and pressure regimes for laminating) for smartcards are disclosed herein.

The present disclosure relates to a smart card device comprising: a laminated core comprising: a front substrate (10); a first flexible sheet (20) having a card circuitry formed thereon; a first substrate (30); a second flexible sheet (40) having an inductive circuitry formed thereon, and a second substrate (50) in a top-to-bottom order, wherein the front substrate (10) provides at least one first opening (11) which defines a perforated design and a second opening (12) through which a contact pad (22) is exposed, wherein the card circuitry includes: a flip chip (21), a first antenna coil (24) conductively coupled to the flip chip (21), the contact pad (22), at least one conductor path (23) conductively coupling the contact pad (22) to the flip chip (21), wherein the inductive circuitry includes at least one LED module (46) arranged proximate to the at least one first opening (11) and a second antenna coil (44) conductively coupled to the at least one LED module (46), and wherein the first substrate (30) includes at least one light guide (31) which is arranged under the at least one first opening (11) and configured to direct an illumination produced by the at least one LED module (46) through the at least one first opening (11) to illuminate the perforated design.