A system, device, and method for a broad-band array antenna are presented. More particularly, the application relates to a broad-band fragmented aperture phased array antenna for the Ka, K, and/or Ku frequency bands. In various exemplary embodiments, the antenna system may support dynamic polarization degradation correction. In one exemplary embodiment a method and system for a broad-band fragmented aperture phased array antenna for the Ka, K, and/or Ku frequency band is presented. In one exemplary embodiment, the fragmented aperture design functions in one or more of the Ku-band, K-band, and/or Ka-band. In another exemplary embodiment, the antenna system may include full electronic polarization agility. In one exemplary embodiment, the antenna system may further comprise a printed circuit board radiating element. The printed circuit board radiating element may be configured to function as an antenna. In one exemplary embodiment, the antenna system may support operation over multiple frequency bands.

An antenna (100) for an RFID reading apparatus is provided having at least one single CLL antenna (10), wherein a single CLL antenna (10) is an antenna that has an inner antenna loop (12) and a capacitively loaded antenna loop (14) which surrounds the inner antenna loop (12) and into which a capacitance (16 is introduced. In this respect, the antenna (100) has a plurality of single CLL antennas (10a-d) that are differently oriented and has a feed circuit (26) to operate the single CLL antennas (10a-d) for generating a circular polarization with a respective phase offset.

A control system is presented for controlling operation of a phased-array antenna comprising N antenna elements each comprising H and V polarization terminals. The control system includes: an analogue circular polarization system (ACTS) and a digital polarization control system (DPCS). The ACPS comprises an array of N analogue circular polarization circuits (ACPCs) associated with said N antenna elements, respectively, such that each ACPC is connectable to the V and H polarization terminals of the respective antenna element. The ACPS is configured and operable with N analog circular polarization signal components each being either left or right circular polarization signal. The DPCS comprises: an array of N convertors associated with said N ACPCs, respectively, for converting between the N analog circular polarization (ACP) signals and N respective digital circular polarization (DCP) signals, such that each antenna element is associated with a respective single one of said N convertors; an array of N digital polarization controlled beamformers (DPCBs) connectable to said N convertors; and a plurality of digital signal splitters and/or combiners. Each DPCB comprises at least two beam forming channels associated with at least two, first and second, respective beams of different beam directions and/or different polarizations being operated by the antenna element, and is configured and operable to apply phase shifting to the respective DCP signal based on data indicative of a beaming direction (α) of a respective beam to be operated and the left or right polarization of circular polarization signal, and a relative phase (Φ) associated with the beaming direction (α) and a location of the respective antenna element in the array, to thereby form at least two phase shifted signals corresponding to said at least two, first and second, respective beams. Digital signal splitters and/or combiners operate to separately combine the phase shifted signals corresponding to respectively the at least first and second beams, wherein at least two convertors of said N convertors are connected to a respective one of the signal splitters and/or combiners, and wherein each digital splitter and/or combiner, connected to the at least two converters, converts between the DCP signals of opposite left and right circular polarizations of the at least two convertors and V and H linear polarization components and splits and/or combines the opposite left and right circular polarization signals of the at least two convertors.

An antenna routing method and related devices are provided. A user terminal equipment includes multiple antenna groups distributed around a periphery of the user terminal equipment. Each antenna group includes two antennas. Two antennas in each antenna group are different in polarization direction. The method includes the following. Two antennas in any one antenna group of the multiple antenna groups are enabled and one antenna in each of two antenna groups adjacent to the any one antenna group is enabled respectively, and a first signal quality of the antennas enabled is measured, to obtain multiple first signal qualities. A set of antennas with the optimal first signal quality is determined according to the multiple first signal qualities, to receive or transmit radio frequency signals.

An example wireless power transmitter includes a ground plate, a conductive wire offset from the ground plate, and a signal-conveyance member. The conductive wire of the wireless power transmitter forms a loop antenna that is configured to radiate a radio frequency (RF) signal for wirelessly powering a receiver device. And the signal-conveyance member of the wireless power transmitter is configured to selectively feed a waveform to a connection point of a plurality of connection points along the conductive wire, wherein the waveform, when provided to the conductive wire, causes the loop antenna to radiate the RF signal.

An array antenna includes a plurality of first patch antennas configured to radiate a polarized wave in an X direction at a first operating frequency and configured to radiate a polarized wave in a Y direction at a second operating frequency higher than the first operating frequency, and a plurality of second patch antennas configured to radiate a polarized wave in the Y direction at the first operating frequency and configured to radiate a polarized wave in the X direction at the second operating frequency. When a distance between any one of the first patch antennas and another one of the first patch antennas closest to the any one first patch antenna is defined as D1, and a distance between any one of the first patch antennas and the second patch antenna closest to the any one first patch antenna is defined as D2, D1>D2 is satisfied.

The technology described herein relates to polarization adaptive wireless power transmission systems. In an implementation, a wireless power transmission system is described. The wireless power transmission system includes an antenna array and control circuitry operatively coupled to the antenna array. The control circuitry is configured to determine polarization information of a beacon signal received from a client device at multiple antennas of the antenna array. The beacon signal is transmitted by a client device in a wireless power delivery environment. The control circuitry is further configured to configure polarization information associated with each of the multiple antennas to match the polarization information determined at respective antennas of the multiple antennas. The present technology enables different wireless power receiver clients to have different polarizations. The wireless power transmission system can efficiently send power to the client devices by matching their polarization.

An RF energy transmitting apparatus with positioning and polarization tracing function is used for an RF energy harvesting apparatus. The RF energy transmitting apparatus includes a power radar transmitter and a radar controller. The power radar transmitter receives a power source signal and emits an electromagnetic source wave. The radar controller is electrically connected to power radar transmitter and receives a reflected harmonic wave. The power radar transmitter emits the electromagnetic source wave to scan a space. The RF energy harvesting apparatus generates and emits the reflected harmonic wave. The radar controller determines a position and a polarization angle of the RF energy harvesting apparatus after receiving the reflected harmonic wave and to adjust a polarization angle of the power radar transmitter to be within a predetermined angle range with respect to the polarization angle of the reflected harmonic wave sent from the RF energy harvesting apparatus.

Antenna assemblies are described herein. In particular, described herein are multi-focal-point antenna devices and compact radio frequency (RF) antenna devices. Any of these assemblies may include a primary feed that includes a single patterned emitting surface from which multiple different beams of RF signals are emitted corresponding to different antenna input feeds each communicating with the patterned antenna emitting surface. The antenna assembly is therefore capable of emitting beams in the same direction having different polarizations using a single primary feed.

A system and method is provided in which a single-pole-double-throw switch controls whether a circular loop transmits a right-hand circular polarized signal or a left-hand circular polarized signal. The single-pole-double-throw switch is shielded from the circular loop by a metallic ground plane. An annulus of dielectric insulates the circular loop from the metallic ground plane.