Abstract: Disclosed is a system including RF circuitry configured to generate an RF signal; a plurality of unit cells configured to receive the RF signal and to cause an RF energy signal having a center frequency to be present within the unit cells; and receiver circuitry configured to charge an electronic device in response to an antenna of the electronic device receiving the RF energy signal when the antenna is tuned to the center frequency and positioned in a near-field distance from one or more of the unit cells.

Abstract: Disclosed is a system including RF circuitry configured to generate an RF signal; a plurality of unit cells configured to receive the RF signal and to cause an RF energy signal having a center frequency to be present within the unit cells; and receiver circuitry configured to charge an electronic device in response to an antenna of the electronic device receiving the RF energy signal when the antenna is tuned to the center frequency and positioned in a near-field distance from one or more of the unit cells.

Abstract: Disclosed is a system including RF circuitry configured to generate an RF signal; a plurality of unit cells configured to receive the RF signal and to cause an RF energy signal having a center frequency to be present within the unit cells; and receiver circuitry configured to charge an electronic device in response to an antenna of the electronic device receiving the RF energy signal when the antenna is tuned to the center frequency and positioned in a near-field distance from one or more of the unit cells.

Abstract: An antenna include a resonator element configured to radiate a wireless signal and a substrate embedding the resonator. The resonator element may be a 3D resonator element. The 3D resonator element may be a helical resonator element.

Abstract: Systems (100) and methods (900) for reading Radio Frequency Identification (“RFID”) tags. The methods comprise: coupling a wearable RFID tag reader directly to a person's hand or forearm; transmitting a first interrogation signal from a first antenna of the wearable RFID tag reader being worn on a person's hand or forearm; receiving, by the wearable RFID reader, a first response signal generated by and transmitted from a first RFID tag in response to the first interrogation signal; and processing the first response signal to identify, locate or track a first object of interest.

Abstract: Systems (100) and methods (400) for determining a Handheld Reader's (“HR”) location within a facility. The methods involve: performing first operations by HR to read RFID tags having locations within the facility that are unknown to the handheld reader; performing second operations by HR to receive signals from RF Enabled Devices (“RFED”) located at known locations within the facility; and determining HR's location/orientation using RSSI levels or TOF values of signals received from RFEDs, known locations of RFEDs, sensor data, known antenna patterns of RFEDs, a known antenna pattern of HR, and/or (9) information indicating which RFID tags were read by HR and at least one RFED. The first and second operations are performed while HR is being carried by a person throughout the facility.

Abstract: Systems (100) and methods (900) for reading Radio Frequency Identification (“RFID”) tags. The methods comprise: coupling a wearable RFID tag reader directly to a person's hand or forearm; transmitting a first interrogation signal from a first antenna of the wearable RFID tag reader being worn on a person's hand or forearm; receiving, by the wearable RFID reader, a first response signal generated by and transmitted from a first RFID tag in response to the first interrogation signal; and processing the first response signal to identify, locate or track a first object of interest.

Abstract: Systems and methods for operating an RFID tag. The methods comprise: inducing current through a magnetic loop or solenoid disposed within the RFID tag that is caused by a inductive field, a magnetic field or an RF field being generated within a surrounding environment; using the current which is induced through the magnetic loop or solenoid to charge a capacitor disposed within the RFID tag; decreasing the amount of current induced through the magnetic loop or solenoid; receiving a detaching signal at the RFID tag; electrically connecting the capacitor to a detaching unit disposed within the RFID tag in response to the detaching signal; and activating the detaching unit by supplying current from the capacitor to the detaching unit, whereby the RFID tag can be detached from an article.

Abstract: Antenna system includes a fixture having a first portion and a second portion joined along an alignment axis. A first planar antenna element having a first polarization direction is aligned with a first plane, and secured to the first portion of the antenna fixture. A second planar antenna element has a second polarization direction aligned with a second plane. The second planar antenna element is secured to the second portion of the antenna fixture so that the second plane is transverse to the first plane and the first and second planes intersect along a line parallel to the alignment axis. At least one tuned element mitigates near-field interference as between the first planar antenna element and the second planar antenna element. Signals applied to the antenna feed port will result in three-polarization radiation.