In a printing device, a supply portion is configured to convey a tape in its longitudinal direction. The tape includes: a plurality of labels arranged continuously in the longitudinal direction; and a plurality of storage elements provided on respective ones of the plurality of labels. A first storage element is provided on a first label and configured to store first authentication data. The second storage element is provided on a second label and configured to store second authentication data. A printing portion is configured to print on the plurality of labels. A controller is configured to perform: reading the first authentication data from the first storage element and the second authentication data from the second storage element by a reading portion; and determining whether the first authentication data is correlated to the second authentication data to meet an authentication condition.

An RFID device is provided with a substrate and a plurality of RFID components associated to the substrate. The substrate is initially provided in a substantially planar configuration, with the RFID components being associated to the substantially planar substrate. After the RFID components have been associated to the substrate, the substrate is folded at least one fold line to give the substrate and resulting RFID device a non-planar structure. All or portions of at least two of the RFID components are associated to portions of the substrate that are present in different planes, which may include portions of the substrate that are oriented in generally parallel planes or at an angle to each other. By such a non-planar, three-dimensional configuration, an RFID device may be provided with enhanced functionality, including increased bandwidth, ability to receive and radiate signals in a plurality of distinct frequency bands, and directivity.

The present invention relates to a method of manufacturing a metal foil laminate which may be used for example to produce an antenna for a radio frequency (RFID) tag, electronic circuit, photovoltaic module or the like. A web of material is provided to at least one cutting station in which a first pattern is generated in the web of material. A further cutting may occur to create additional modifications in order to provide additional features for the intended end use of the product. The cutting may be performed by a laser either alone or in combinations with other cutting technologies.

A feedback control system for RFID assembly production. The control system can include a measurement system and a control system. The measurement system may take measurements of one or more electrical properties of an RFID chip assembly, for example an RFID strap or RFID antenna. The measurement system may then communicate to the control system to adjust one or more parameters affecting the electrical properties. Once the desired set of electrical properties is achieved, the chip assembly may be cured. The feedback control system may be implemented dynamically, either for precision assembly of individual chip assemblies or in batch for controlling the average properties of assemblies on a rolling production line. The feedback control system can also be implemented in a step-wise fashion and be used to collect data and iteratively self-improve.

Metal layers of a smartcard 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. Pre-laminated metal layers having an array of card sites, with each position having a defined area prepared for the later implanting of a transponder chip module characterized by different sized perforations and gaps around this defined area adjacent to the RFID slit(s), to facilitate the quick removal of the metal in creating a pocket to accept a transponder chip module.

The invention relates to a method for producing a support body in a card format, with a graphic customization, that has a surface finishing effect that is more or less smooth, rough, mirrored or matte on the support body. The method includes supplying a support body having a layer of material configured to allow a marking by punching or lamination. The layer is exposed on the main external face and the surface finishing effect is equivalent to that obtained by a step of marking or lamination while not including a step of depositing varnish.

Aspects of the present disclosure includes a method of manufacturing a radio frequency identification (RFID) tag, including connecting a first wire and a second wire across a chip, maintaining the spaced apart distance between the first wire and the second wire adjacent to each side of the chip to define a spaced apart segment of the first wire and the second wire that forms part of an inductive loop, connecting the first wire and the second wire at each side of the chip distal from and adjacent to the spaced apart segment of the first wire and the second wire to close the inductive loop, define connected wire segments, and to form an RFID assembly, and moving the RFID assembly through a casing material at or above a glass transition temperature of the casing material to encase the RFID assembly.

Method and apparatus for producing RFID transponders (400) arranged on a carrying substrate, comprising:providing a first substrate (100), the first substrate having at least one antenna element (101) arranged thereon, and preferably several antenna elements arranged sequentially thereon along a longitudinal extension of the first substrate, each antenna element being formed by an electrically conductive pattern; providing a second substrate (200), the second substrate (200) having at least one RFID strap, each RFID strap comprising an IC (202) and at least one contact pad (201) coupled to the IC, and preferably several RFID straps being arranged sequentially along a longitudinal extension of the second substrate; and electrically connecting an antenna element (101) on the first substrate to the at least one contact pad on the second substrate by bringing said first and second substrates together, thereby bringing said antenna element in mechanical contact with said at least one contact pad, and heating the contact pad(s) to a temperature at least equal to a characteristic melting point of said at least contact pads, thereby electrically connecting the antenna element to said at least one contact pad.

The invention relates to a system for preparing a radiofrequency identification tag for attachment to a support, the system comprising a placement device configured to place the tag on the support, the placement device comprising a displacement member that is movable between a loading position and a placement position, and a holding member having a configuration for releasing the tag and a configuration for holding the tag, the holding member being in the configuration for holding the tag during a movement of the displacement member between the loading position and the placement position. The system makes it possible to automate the placement of the tag for its attachment to the support, for example a textile.

The present invention relates to an RFID label comprising an RFID tag which tag comprises an RFID antenna and an IC, which IC is attached onto the antenna such that the antenna and the IC forms the RFID tag. The inventive label further comprising an elongated substrate with a first surface and a second surface, wherein the first surface is siliconized, and the second surface is carrying the RFID tag, and a sticky adhesive layer which is arranged onto the second surface of the substrate and over the RFID tag.