In a method of producing a transponder (T1, T2, T3), a substrate (1, 91) is provided. The substrate (9, 91) comprises a first area (2), a second area (3) adjacent to the first area (2), and a first electric contact (8, 98) adjacent to the second area (3). An electric device (50, 80) is placed in or on the first area (2), preferably without touching the first electric contact (8, 98). Subsequently, a conductive glue (12) is applied on the second area (3) and on the first electric contact (8, 98) so that the conductive glue (12) electrically couples the first electric contact (8, 98) with the electric device (50, 80).

Method for manufacturing an RFID tag comprising an IC and an antenna. The method comprising the steps of providing an antenna made of a soldering material, which antenna is at least partly covered with a hot melt adhesive in solid form; heating the antenna to a temperature above its melting point, wherein the heated parts of the antenna and the hot melt adhesive melt, placing an IC in a predetermined position which position is suitable for the IC to connect to the antenna; pressing the IC and antenna together, such that, an electrical connection between the IC and the antenna is established; and cooling RFID tag, such that the hot melt adhesive and the antenna solidify, wherein a soldered joint between the IC and the antenna is achieved and the hot melt adhesive surrounds the joint between the IC and the antenna.

An RFID tag assembly and method of use with a RFID tag assembly the RFID tag assembly includes an RFID tag having a mounting substrate having a spacer with a first surface and an opposing second surface, the spacer having a predetermined thickness, a mounting carrier with a substantially planar body with a first portion having first and second ends with two sides defined therebetween and has two or more second portions extending from the body forming free ends each and having selectively attachable adhesive on a portion of the bottom surface being deformably attached to the first portion and with second surface attached to the top surface of the first portion with the first planar surface with the RFID tag position parallel and set apart above the top surface of the carrier at a distance equal to or greater than the predetermined thickness.

A non-contact data receiving/transmitting body is provided which includes an IC chip, a first antenna to which the IC chip is connected, and a second antenna for use as a booster that resonates with the first antenna in a non-contact manner. The first antenna is a ring-shaped antenna having at least three straight portions. The second antenna has a central portion that is bent such that parts of the central portion extend respectively along the three straight portions of the first antenna and are at an angle equal to or greater than 90° to each other. The IC chip is provided on the three straight portions of the first antenna and is connected to the first antenna at the straight portions.

A method for manufacture of an electronic interface card including defining a pair of apertures in a substrate layer, associating an antenna with the substrate layer such that opposite ends of the antenna terminate at the apertures, placing a metal element in each of the apertures, connecting the ends of the antenna to the metal elements, laminating the substrate layer together with a top layer and a bottom layer, forming a recess in the top layer and the substrate layer, attaching ends of connection wires to the metal elements, attaching opposite ends of the connection wires to a chip module and sealing the chip module in the recess.

A transaction card having an opening in a metal card body, a booster antenna in the opening, and a molding material about the booster antenna. A process for manufacturing the transaction card includes forming an opening in a card body, inserting a booster antenna into the opening, and molding a molding material about the booster antenna.

An electronically addressable object carrier for enabling the management of removably suspended objects, such as keys, distributed in an object location space, The object carrier includes a housing having an object retention element for securing an object to the object carrier and at least one through aperture for removably receiving an electrically conductive suspension member capable of manifesting object address signals and power signals supplied by a source; a microcontroller carried by the housing, the microcontroller having a unique object address serving to identify an object secured to the object carrier; an electrically conductive element located in the at least one aperture for electrically coupling the microcontroller to the electrically conductive suspension member when the aperture is removably received on the electrically conductive suspension member; and a visible indicator coupled to the microcontroller for activation whenever the microcontroller receives an address signal representative of the unique object address. Two electrically conductive elements can be used: one having first and second electrically conductive members slidably and oppositely disposed in a single aperture and bias means for urging the first and second electrically conductive members toward each other to make contact with an electrically conductive suspension member when the carrier is mounted. Another being a pair of washers mounted in spaced first and second apertures in the housing. In use, the devices are removably suspended by one or two electrically conductive suspension members secured to a support element, such as the back board of a cabinet.

A transaction card construction and a method for making transaction cards provides increased security for transaction card magnetic strips. The transaction card construct on includes a card inlay and a clear card body. The card inlay is formed via a lamination press process with the magnetic strip attached to a back surface of the card inlay. The card body may have a window through which a data storage element may be exposed for accessing, such as by a magnetic stripe reader or EMV chip reader. The card body may be formed by adhering the card inlay to the clear card body.

A process for manufacturing an electronic module intended to be implemented in a dual-interface portable object is provided. The process includes at least the following steps: Using a single-sided film consisting of one or more contact regions and a dielectric comprising one or more apertures, Using a substrate comprising one or more electrically conductive regions intended for the contactless communication of the object, Securing said single-sided film and said substrate together, Positioning an integrated circuit and connecting it to the contact regions of the single-sided film and at least to one terminal of at least one of said electrically conductive regions, Depositing a protective layer incorporating at least said integrated circuit.

Also provided is a module obtained by means of the process.

Brackets for amplifying antenna gain associated with mountable radio frequency identification (RFID) tags are disclosed. An example apparatus includes a bracket and an RFID tag. The bracket has a base, a first meandering amplification arm connected to and extending away from the base in a first direction, and a second meandering amplification arm connected to and extending away from the base in a second direction opposite the first direction. The RFID tag is mounted to the base of the bracket. The first meandering amplification arm and the second meandering amplification arm are respectively structured to at least one of: amplify an antenna gain associated with the RFID tag; or increase a communication range associated with the RFID tag.