An RFID mesh label configured to be integrally incorporated within a vulcanized tire and to further provide unique identifier(s) and/or other information about the vulcanized tire during and/or post-vulcanization, the RFID mesh label including a face layer configured to be positioned adjacent or flush to an outer surface of the vulcanized tire; an RFID layer positioned underneath the face layer, the RFID layer having an RFID device that is configured to provide unique identifier(s) and/or other information about the vulcanized tire upon being read with an RFID reader; and a mesh backing overlying the RFID layer and adapted to be integrally incorporated in a vulcanized tire after subjecting a green tire to a vulcanization process.

An Internet of Thing (IoT) device includes a body with a processor, a camera and a wireless transceiver coupled to the processor.

A wristband configuration for receiving an accessory is described herein. In some implementations, a wristband includes a first side that includes a printable section of the wristband that includes a print coating. The wristband may include a second side, opposite the first side, that includes. The wristband may include may include a comfort coating, and an adhesive material on an adhesive section of the wristband. The wristband may include a receiving hole pattern that is configured to receive an accessory associated with the wristband and secure the accessory to the wristband when worn by a wearer.

Aspects of the present disclosure relate to an apparatus comprising: a substrate; communication circuitry deposited on said substrate; and ballot circuitry deposited on said substrate. The ballot circuitry comprises: a plurality of voting circuitry elements, each voting circuitry element being responsive to a voting operation to change a conductive state of that voting circuitry element; and logic circuitry communicatively coupled with each of the plurality of voting circuitry elements and with the communication circuitry. The logic circuitry is configured to: detect the conductive state of each of the plurality of voting circuitry elements; and transmit, via the communication circuitry and based on the conductive state of each of the plurality of voting circuitry elements, a voting result.

For example, provided is an RFID-bearing flexible material, in which an RFID is attached to a flexible material, the RFID includes an antenna portion, and the antenna portion is formed of a conductive linear body containing a carbon nanotube yarn.

An Internet of Thing (IoT) device includes a body with a processor, a camera and a wireless transceiver coupled to the processor.

A flexible chip card such as a credit card or a debit card that incorporates a protective layer that precludes unauthorized access to the chip in the chip card. The protective layer is a highly conductive layer that shields the chip and prevents electromagnetic waves that may be emitted by an illicit device from accessing the chip. This protective layer thus prevents any unauthorized persons from obtaining confidential information from the chip card that may then be used to consummate fraudulent transactions or conduct other illicit activities. In one embodiment, the flexible chip card includes one or more stiffening structures to provide rigidity to the chip card.

Disclosed herein are Flexible Radio Beacons and Flexible Delivery Structures for asset and inventory identification and management. The Flexible Radio Beacon is dormant until activated at time of use. The Flexible Radio Beacon has optional activation means and can be activated physically or electronically. The Flexible Radio Beacon and Flexible Delivery Structures make a flexible radio frequency (RF) tag useful for asset tracking. Disclosed herein is a method for using Flexible Radio Beacons and Flexible Delivery Structures in flexible RF tags for asset and inventory identification and management. Disclosed herein is a system for asset and inventory identification and management using Flexible Radio Beacons and Flexible Delivery Structures in flexible RF tags.

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.

Systems and methods of tracking distribution items using hardware components on or in the distribution items. Shippers and recipients of distribution items can track or locate a distribution item, especially a high value item, if the distribution item is lost, misrouted, or delayed.