A device has a substrate, a plurality of switches located on the substrate, a plurality of NFC chips, each associated with a switch, and an NFC antenna. The switches and the NFC chips associated therewith are interconnected in series and are connected to the NFC antenna. The device contains a label which is joined face to face with the substrate, the individual NFC chips are arranged on the label. The switches are arranged on the substrate but not on the label, and mutually opposed contact points contacting the conductor tracks with each other are provided on the substrate and on the label to electrically connect the switches, the NFC chips and the NFC antenna.

A lead frame used to assemble a semiconductor device, such as a smart card, has a first major surface including exposed leads and a second major surface including a die receiving area and one or more connection pads surrounding the die receiving area. The connection pads enable electrical connection of an Integrated Circuit (IC) die to the exposed leads. A molding tape sized and shaped like the lead frame is adhered to and covers the second major surface of the lead frame. The molding tape has a die receiving area cut-out that exposes the die receiving area and the connection pads on the second major surface of the lead frame and forms a cavity for receiving an encapsulant. The cut-out has an elevated sidewall for retaining the encapsulant within the cavity.

A packaging paperboard is provided that includes two or more layers with an antenna pattern printed on one layer of the two or more layers, and an RFIC element adhered to the other layer of the two or more layers. In a laminate having the layers stuck together, the RFIC element and the antenna pattern are interposed between the layers to configure an RFIC device in which the RFIC element and the antenna pattern are electrically connected.

A chip card manufacturing method. A module includes a substrate supporting contacts on one surface and conductive paths and a chip on another; and an antenna on a holder, the antenna including a contact pad for respectively connecting to each of the ends thereof. A solder drop is placed on each of the contact pads of the antenna. The holder of the antenna is inserted between plastic layers. A cavity is provided, in which the module can be accommodated and the solder drops remain accessible. The height of the solder drops before heating is suitable for projecting into the cavity. A module is placed in each cavity. The areas of the module that are located on the solder drops are heated to melt the solder and to solder the contact pads of the antenna to conductive paths of the module.

A radio frequency identification (RFID) switch tag is disclosed. This RFID switch tag includes a base component having an ultra-high frequency (UHF) booster, and a detachable component having at least one UHF RFID module and a high frequency (HF) RFID module. In some embodiments, the detachable component is positioned in close proximity to the base component in a first configuration of the RFID switch tag such that the at least one UHF RFID module is sufficiently coupled to the UHF booster in the base component to form an UHF RFID system having a desired performance. The detachable component can also be separated from the base component to obtain a second configuration of the RFID switch tag, and the HF RFID module remains functional within the detached detachable component so that the detachable component can be used as a standalone HF RFID tag.

Embodiments of the invention provide an integrated chip (IC) module having contact pads which are accessible by single-bond holes and module-side antenna contact pads which are accessible by multi-bond holes. Each multi-bond hole is apportioned by an encapsulation into adjoining bonding channels for separately receiving wire bond(s) and antenna-connecting element. Each module-side antenna contact pad is apportioned by the encapsulation into adjoining but electrically connected bonding areas to allow establishment of electrical connection of both wire bond(s) and antenna-connecting element to an IC chip. The first and the second bonding area are partitioned from each other, by the encapsulant, without requiring a presence of substrate therebetween.

Smartcard (SC) having a card body (CB) and a conductive coupling frame antenna (CFA) extending as a closed loop circuit around a periphery of the card body, and also extending inwardly so that two portions of the coupling frame antenna are closely adjacent each other, with a gap therebetween. The gap may extend from a periphery of the card body to a position corresponding with a module antenna (MA) of a transponder chip module (TCM) disposed in the card body, and may function like a slit (S) in a coupling frame (CF). A portion of the coupling frame antenna may be arranged to surround the ISO position of the transponder chip module in the card body. A coupling frame antenna (CFA) may be incorporated onto a module tape (MT) for a transponder chip module (TCM).

The invention relates to a method for fabricating chip cards. According to this method, an antenna and a chip card module are provided. This chip card module includes a dielectric substrate and conducting tracks at least on a face of this substrate. A connection unit is used to establish a connection between the antenna and conducting tracks of the module. The invention also relates to a method for fabricating an antenna support including such a connection unit. The invention also relates to a chip card and an antenna support which are obtained by the aforementioned methods.

The present invention aims to provide an RFID tag capable of improving antenna efficiency with a simple configuration. Such an RFID tag includes: an antenna configured with a reader/writer; an IC chip to which the antenna is connected; a plurality of connection terminals inside outer peripheral edges of an insulating layer on which the antenna is formed; and an annular antenna-forming area on the entire periphery or substantially the entire periphery of the insulating layer. The antenna is formed into a loop in the antenna-forming area, with one of the plurality of connection terminals serving as a starting point and with one of the remaining connection terminals serving as an endpoint.

An antenna includes first and second radiation portions including one lead wire that is folded back into a loop shape to define a folded-back portion and that includes a first power feed portion at a first end and a second power feed portion at a second end. The lead wire portion extending toward the folded-back portion and the lead wire portion extending through the folded-back portion are close enough to each other near each of the first and second power feed portions in the first and second radiation portions, respectively, to be electromagnetically coupled to each other. The power feed portions of the antenna are coupled to a wireless IC chip. The power feed portions may be coupled to a feed circuit in a feed circuit board coupled to a wireless IC.