A near-field communication device having one or more processors configured to control the near-field communication device, an energy supplier having an energy supply circuit and a supply antenna configured to provide energy to a second antenna circuit arranged externally to the near-field communication device, wherein the supply antenna of the energy supplier is galvanically coupled to the energy supply circuit, and a first antenna circuit having a first communication circuit and a first antenna, wherein the first communication circuit is configured for communication with a second communication circuit of the second antenna circuit by means of an inductive coupling by means of the first antenna of the first antenna circuit.

An RF lens includes a multitude of radiators adapted to transmit radio frequency electromagnetic EM waves whose phases are modulated so as to concentrate the radiated power in a small volume of space in order to power an electronic device positioned in that space. Accordingly, the waves emitted by the radiators are caused to interfere constructively at that space. The multitude of radiators are optionally formed in a one-dimensional or two-dimensional array. The electromagnetic waves radiated by the radiators have the same frequency but variable amplitudes.

Circuits, systems and computer readable media transmission of wireless signals in response to incoming signals in a wireless signaling environment. Such a system may include at least one transceiver for receiving an incoming signal via an antenna array from a device in the wireless signaling environment. The system may also include a controller operably coupled to the transceiver. The controller may measure a phase of the incoming signal, and determine, based on the phase, a transmit phase configuration for one or more antennas of the antenna array. The system may include at least one phase-locked loop (PLL) operably coupled to the transceiver(s). The PLL(s) may feed signals to the antenna(s) of the antenna array based on the transmit phase configuration for transmission of a responsive signal to the device.

A power transfer system comprises a patient transport apparatus and a power transfer device. The power transfer system provides convenience and ease of connection between a power source and the patient transport apparatus to provide power to one or more electrically powered devices on the patient transport apparatus or to provide energy for an energy storage device on the patient transport apparatus.

A device for high-frequency communication and for the inductive charging of an apparatus, including a charging surface, at least one charging antenna emitting a magnetic field at a low frequency and a layer of ferromagnetic material. The device includes at least one communication antenna and a printed circuit board. The communication antenna is in the form of a coil locally surrounding the layer with an axis of symmetry located in a plane parallel to the layer. The material of the layer is selected so as to have, at high frequency, an imaginary part with sufficiently high permeability to generate leaks on a surface of the layer extending perpendicular to the layer, while at the same time maintaining, at low frequency, an imaginary part with sufficiently low permeability to allow inductive charging.

A wireless power transfer system includes a wireless power transfer device configured to determine a magnetic field, from among a plurality of directionally different potential magnetic fields that the wireless power transfer device is configured to generate, that has, at a receiver coil of an electronic device, a direction aligned with the receiver coil.

A wireless power transmission system includes a power transmitter that outputs a power transmission radio wave, a plurality of wireless sensors that receive power, and at least one human body tag to be carried on a human body in an environment. The power transmitter communicates with the at least one human body tag in each slot to estimate power exposure on a human body per slot for a human body carrying the at least one human body tag, calculates power exposure on a human body per cycle as an average of power exposure on a human body for all slots, and limits power transmission to the wireless sensors in response to the power exposure on a human body per cycle exceeding a predetermined value.

A wireless power transmission apparatus is disclosed. The wireless power transmission apparatus comprises: a first plate having a first polarity, a second plate spaced apart from the first plate and having a second polarity different from the first polarity, at least one wireless power transmission module disposed between the first plate and the second plate and connected to one side of the first plate and one side of the second plate, and a processor configured to control the wireless power transmission module, wherein the processor is configured to move the wireless power transmission module to a location corresponding to one area between the first plate and the second plate based on a wireless power receipt apparatus being identified in one area of another side of the second plate.

This disclosure relates to a power efficient wireless power receiver that is configured to receive and convert wireless power to direct-current (DC) power with minimal wastage. In particular, the receiver is able to selectively switch between a DC power combining topology and a radio-frequency (RF) power combining topology based on the amount of power that has been received so that the maximum amount of power received is optimized.

Systems, methods and apparatus for wireless charging are disclosed. A wireless charging device has a first plurality of charging coils provided at a charging surface of the wireless charging device, and a controller. The controller may be configured to determine that a chargeable device is positioned proximate to a plurality of charging coils provided in a charging surface, decouple a first charging coil in the plurality of charging coils from a first driver circuit, couple the first charging coil to a second driver circuit, where a second charging coil in the plurality of charging coils may be coupled to the second driver circuit, and configure the charging current supplied by the second driver circuit to cause the first charging coil and the second charging coil to transfer a desired power level to the chargeable device.