The invention relates to a method for inductive energy transmission from a transmitting coil to a receiving coil spaced apart from the transmitting coil. The receiving coil is arranged in a vehicle which is arranged stationary or is travelling on a supporting surface, wherein the vehicle has at least one sensor. In a first method step (A) a distance between the transmitting coil and/or the supporting surface and the receiving coil is determined, in a second method step (B) a minimum possible air gap between the transmitting coil and/or the supporting surface and the receiving coil is calculated from the distance, and in a third method step (C) the receiving coil is positioned such that the distance corresponds to the minimum possible air gap.

The invention relates to a method for inductive energy transmission from a transmitting coil to a receiving coil spaced apart from the transmitting coil. The receiving coil is arranged in a vehicle which is arranged stationary or is travelling on a supporting surface, wherein the vehicle has at least one sensor. In a first method step (A) a distance between the transmitting coil and/or the supporting surface and the receiving coil is determined, in a second method step (B) a minimum possible air gap between the transmitting coil and/or the supporting surface and the receiving coil is calculated from the distance, and in a third method step (C) the receiving coil is positioned such that the distance corresponds to the minimum possible air gap.

Systems, methods and apparatus for wireless charging are disclosed. A charging device has a plurality of charging cells provided on a charging surface provided at a charging surface of the wireless charging device, and a controller. The controller may be configured to provide a charging current to at least one active transmitting coil in the charging surface, measure voltages across three or more transmitting coils in the charging surface and determine that the chargeable device is in motion across the charging surface based on changes in the voltages measured across the three or more transmitting coils. The charging current may cause a wireless transfer of power through the at least one active transmitting coil to a chargeable device located on the charging surface.

Systems, methods and apparatus for wireless charging are disclosed. A charging device has a plurality of charging cells provided on a charging surface provided at a charging surface of the wireless charging device, and a controller. The controller may be configured to provide a charging current to at least one active transmitting coil in the charging surface, measure voltages across three or more transmitting coils in the charging surface and determine that the chargeable device is in motion across the charging surface based on changes in the voltages measured across the three or more transmitting coils. The charging current may cause a wireless transfer of power through the at least one active transmitting coil to a chargeable device located on the charging surface.

A wireless charging positioning device and method, a receiver and a storage medium are provided. The device is applied to a transmitter and includes: at least one group of detection coils and at least one processor. Each group of detection coils includes N detection coils, detection regions covered by different detection coils are at least partially different, detection coil is configured to transmit a detection signal and receive a feedback signal sent by a receiver, and N is a positive integer greater than or equal to 2. The at least one processor is connected with the N detection coils and configured to determine a position region of the receiver at the transmitter according to the feedback signals received by the N detection coils.

A wireless charging positioning device and method, a receiver and a storage medium are provided. The device is applied to a transmitter and includes: at least one group of detection coils and at least one processor. Each group of detection coils includes N detection coils, detection regions covered by different detection coils are at least partially different, detection coil is configured to transmit a detection signal and receive a feedback signal sent by a receiver, and N is a positive integer greater than or equal to 2. The at least one processor is connected with the N detection coils and configured to determine a position region of the receiver at the transmitter according to the feedback signals received by the N detection coils.

A near-field communication (NFC) antenna structure for radiation enhancement of a computing device that includes a ferrite sheet, separated into two sections. The NFC antenna structure may be used to improve (i) the magnetic field strength generated by an NFC antenna and (ii) inductive coupling to a receiving antenna of another computing device. A first ferrite section may be placed on a first side of the NFC antenna to at least partially overlap the NFC antenna, and a second ferrite section may be placed on a second side (opposite the first side) to at least partially overlap the NFC antenna. The first ferrite section may be positioned towards a top end that is often positioned closest to a receiving device, as held by a user when performing a contactless communication of the computing device, to increase the magnetic field strength and improve the inductive coupling at the top end.

A watch band changing cradle for a smart watch eliminates the need to use a finger nail to press release buttons on the backside surface of a smart watch when changing or swapping watch bands using slide-in band attachment fittings. The cradle is configured so that the smart watch nests and naturally aligns itself in the cradle so that release protrusions in the cradle can be used reliably to depress the release buttons on the backside of the smart watch. The cradle can be adapted to hold a disc-shaped induction charging pad which is magnetically attracted to the smart watch. The cradle can make the smart watch easier to stow when charging, and the magnetic attraction helps to align and hold the smart watch in the cradle.

A watch band changing cradle for a smart watch eliminates the need to use a finger nail to press release buttons on the backside surface of a smart watch when changing or swapping watch bands using slide-in band attachment fittings. The cradle is configured so that the smart watch nests and naturally aligns itself in the cradle so that release protrusions in the cradle can be used reliably to depress the release buttons on the backside of the smart watch. The cradle can be adapted to hold a disc-shaped induction charging pad which is magnetically attracted to the smart watch. The cradle can make the smart watch easier to stow when charging, and the magnetic attraction helps to align and hold the smart watch in the cradle.

An information handling system with a wireless charging device may include a processor; a memory; a power management unit (PMU); an antenna controller to provide instructions to a radio to cause an antenna to transceive wirelessly with a network; a wireless charging scheduling controller configured to: receive transmission scheduling data from the antenna controller descriptive of when the radio is transmitting and receiving data to and from the network; and initiate, at a charging coil of the wireless charging device, a charging procedure to wirelessly charge a power storage device when the transmission scheduling data indicates that the radio is receiving data from the network or is idle.