A tool having a detectable wireless marker or tag is provided. The tool has a working portion with a projection or tang by which the working portion of the tool is held, a wireless tag located on, but insulated from the tang, and a handle disposed over and encompassing the projection or tang and the wireless tag. In an exemplary embodiment, the wireless tag is insulated from the tang using a housing assembly made up of an inner holder, an outer holder, and the detectable wireless tag positioned between the inner and outer holders. The invention allows for the use of fragile markers or tags, which are protected by the housing assembly from temperatures and pressures used during, for example, tool handle manufacturing processes. Also provided is a method for providing a tool with a detectable wireless tag, and a method for tracking and tracing tools used within a packaging facility.

An RFID tag is provided with a base member, an antenna portion and an IC chip. A split-ring resonator portion of the antenna portion has a first part and a second part. First end portions of the first part are provided with a first facing portion and a first connection portion, respectively. Second end portions of the second part are provided with a second facing portion and a second connection portion, respectively. The first and the second facing portions are apart from and face each other. A third end portion of the impedance matching portion is connected to the first part between the first facing portion and the first connection portion, and another third end portion is connected to the second part between the second facing portion and the second connection portion. The IC chip is connected to the first connection portion and the second connection portion.

A combined EAS and RFID circuit includes an HF coil antenna, a UHF tuning loop, and an RFID chip coupled to a strap that includes a first coupling area and a second coupling area. The coil ends of the HF coil antenna are configured to capacitively and/or conductively couple to one or both of the first coupling area or second coupling area of the strap. The HF coil antenna can include a gap between turns for non-interfering placement of the UHF tuning loop. The EAS circuit can be deactivating upon application of a field at the resonant frequency of sufficient intensity to cause the breakdown voltage to be exceeded between a coil end and coupling area. The threshold breakdown voltage between a coil end and a coupling area can be reduced by laser ablation treatment of a conductive surface of one or both of the coil end or coupling area.

A dual security tag including an RFID component and an electronic article surveillance (EAS) component, respectively disposed on opposite sides of a PET carrier substrate, is provided. The RFID component may include one or more ultra-high frequency antennae, such as a near field loop antenna and a far field dipole antenna, and an integrated circuit (IC) chip. The EAS component may be provided as an RF device, an acoustic-magnetic (AM) device, a low power Bluetooth (BLE) device, or other suitable device. The security tag may also include a facesheet affixed to the RFID component, a release liner layer affixed to the EAS device, and one or more intermediary films or protective layers. A method for manufacturing a dual security tag is also described.

Disclosed are combination radio frequency identification (RFID) and electronic article surveillance (EAS) tags and methods of producing such tags using a converting machine. The method is characterized by feeding a first roll carrying first type inlays and a second roll carrying second type inlays into a converting machine; and, transferring, using the converting machine, the first type inlays to a surface of the second type inlays, thereby forming a two-layer tape carrying pairs of first and second type inlays, each of the pairs comprising an RFID inlay and an EAS inlay, wherein there is no overlap of an RFID antenna element of each RFID inlay and an EAS antenna element of a paired EAS inlay, and wherein the RFID inlay and the EAS inlay of each pair are functionally independent.

A chip packaging structure includes a chip module and a main body, wherein the main body has a first portion, a second portion, and a holding portion. The second portion protrudes from the first portion, and a size of the second portion is less than a size of the first portion. The holding portion is located at the second portion, and the chip module is placed at the holding portion to be engaged with the main body.

A biological sample storage container and a dual chip wireless identification tag thereof are provided. The dual chip wireless identification tag includes a substrate, an antenna structure, a first chip, and a second chip. The antenna structure is disposed on the substrate, and includes two radiation parts and two matching parts. The two matching parts are connected between the two radiation parts, the first chip is coupled to one of the matching parts, and the second chip is coupled to the other one of the matching parts.

An inventory system configured for detecting and counting potentially retained surgical items within a body of a patient includes a tag configured to transmit a return signal including an electrical characteristic when energized, a signal generator configured to generate an energizing signal for the tag, an antenna operably coupled to the signal generator and configured to receive at least the return signal transmitted by the tag, a processor, and a memory. The memory includes instructions stored thereon, which, when executed by the processor, cause the inventory system to energize the tag by the energizing signal, receive the return signal from the tag by the antenna, and determine a presence of the beacon tag based on the electrical characteristic.

Systems and methods for operating a tag system. The methods comprising: emitting a wireless signal from an antenna of the tag with a first signal characteristic when the tag is proximate to an active antenna modulation marker; changing an impedance of a sensor from a first impedance value to a second impedance value when the active antenna modulation marker is exposed to a stimulus; and emitting a wireless signal from the antenna of the tag with a second signal characteristic when the tag is proximate to the active antenna modulation marker and the sensor has the second impedance value.

A Radio Frequency Identification (RFID) system for attaching to fabrics, includes a device having a dielectric base and cover layers, and a conductive foil having a slit. The conductive foil is provided between the dielectric base and cover layers, and is configured to refract magnetic waves emitted by an RFID reader. Further, a rigid electronic module having an antenna that fits in the slit. The rigid electronic module is provided between the conductive foil and the dielectric cover layer. Said slit being longitudinal and centred on the conductive foil to allow distribution of the magnetic field lines. The magnetic field crosses the conductive foil through the slit, thereby activating the rigid electronic module and amplifying a signal emitted thereby. Furthermore, a fabric layer structurally supports said device. The dielectric base and cover layers, the rigid electronic module, the conductive foil, and the fabric layer are fused together.