Embodiments describe a wireless charging device including: a housing having a charging surface, the housing including first and second walls defining an interior cavity; a transmitter coil arrangement disposed within the interior cavity; a plurality of cowlings for confining the plurality of planar transmitter coils in their respective positions; an interconnection structure positioned within the interior cavity between the transmitter coil arrangement and the second wall, the interconnection structure including a plurality of packaged electrical components mounted onto the interconnection structure; and a plurality of standoffs coupled to the interconnection structure and configured to electrically couple the transmitter coil arrangement to the plurality of packaged electrical components.

Disclosed are a wireless charging pad including a plurality of small power transmission coils and a device for and a method of driving the wireless charging pad. More particularly, the wireless charging apparatus includes a driving controller configured to generate a first control signal so as to apply a first driving voltage having a first phase to power transmission coils to be driven matching a device to be charged among the small power transmission coils and generate a second control signal so as to apply a second driving voltage having a phase opposite to the first phase to power transmission coils surrounding the power transmission coils to be driven; and a coil driver configured to apply the first and second driving signals to a wireless charging pad.

A charging system for an Implantable Medical Device (IMD) is disclosed having a charging coil and one or more sense coils. The charging coil and one or more sense coils are preferably housed in a charging coil assembly coupled to an electronics module by a cable. The charging coil is preferably a wire winding, while the one or more sense coils are concentric with the charging coil and preferably formed in one or more traces of a circuit board. The magnitude of one or more voltages induced on the one or more sense coils can be measured to determine the position of the charging coil relative to the IMD, and in particular whether the charging coil is (i) centered, (ii) not centered but not misaligned, or (iii) misaligned, with respect to the IMD being charged, which three conditions sequentially comprise lower coupling between the charging coil and the IMD.

An electronic device comprises: a first cover constituting the front surface of the electronic device; a second cover constituting the rear surface of the electronic device; a memory included in a space formed between the first cover and the second cover; a processor included in the space and electrically connected with the memory; a first antenna and a second antenna included in the space and electrically connected with the processor; and a switch included in the space and connected to the first antenna and/or the second antenna, wherein the memory can include, during execution, instructions for: allowing the first antenna and the second antenna to be connected by shorting the switch when the processor executes a function corresponding to the first antenna; and allowing the first antenna and the second antenna to transmit magnetic field signals together. Other examples are also possible.

Methods, systems, and devices for inductively charging a vehicle. The inductive charging system includes multiple inductive coils for receiving a wireless transferred power. The inductive charging system includes a power electronics circuit that converts the wireless transferred power to a DC current and one or more power storage devices for storing the electrical energy by charging the one or more power storage devices using the DC current. The inductive charging system includes one or more motors configured to move the vehicle using the electrical energy. The inductive charging system includes an electronic control unit that is configured to control at least one of an amount of the electrical energy that is stored in each of the one or more power storage devices or an amount of the electrical energy that is distributed to the one or more motors to move the vehicle.

This disclosure relates to the inductive charging of portable electronic devices. In particular, a charging assembly is disclosed that allows a portable electronic device to be charged in multiple orientations with respect to a charging device. The charging assembly includes two or more separate inductive receiving coils. The inductive receiving coils can be arranged orthogonally with respect to one another by wrapping one or more secondary receiving coils around a ferritic core having two legs extending in different directions from a joint region. By orienting the receiving coils orthogonally with respect to one another, the likelihood of at least one of the receiving coils being aligned with a charging field emitted by a charging device increases substantially.

Device for determining position in space relative to a similar device includes a movable enclosure on which two loop antennas are mounted, besides, the device includes, for each antenna, an EMF sensor of induced EMF when an RF signal is emitted by the similar device is emitted, and a processor that calculates amplitudes and orientations of magnetic field generated by antennas of the similar device, wherein direction vector is based on directions and orientations of magnetic field strengths. An RF signal generator generates an RF signal of a predetermined frequency and amplitude for the antennas, where the EMF sensors operate alternately with the RF signal generator; and a unit for determining the direction to the similar device based on a gradient of magnetic field emitted by the antennas of the similar device.

A coil arrangement for a programming device has a transmitting coil that is set up to emit a transmitted signal, and multiple receiving coils that are set up to receive a received signal. The transmitting coil and the receiving coils are arranged such that the magnetic fluxes generated in the receiving coils by a transmitted signal emitted from the transmitting coil essentially cancel out each other or the voltages induced in the receiving coils by a transmitted signal emitted from the transmitting coil essentially cancel out each other. In addition, a programming device has such a coil arrangement.

A portable terminal is provided. The portable terminal includes a shielding member attached to an inner surface of an external part, a shielding wall formed on the shielding member, a first coil attached to a surface of the shielding member that faces the inner surface of the external part, and a second coil attached to the surface of the shielding member, with the second coil surrounds the first coil on a same plane and the shielding wall being disposed between the first and second coil.

A wireless charging system (transmitter) has multiple transmit coils that allows for multiple receiver devices (receivers), such as cell phones, to be charged simultaneously. The receivers send data packets that include a receiver ID to the transmitter so that one of the transmitter coils can be paired with a respective one of the receivers. The transmitter can then distinguish between the communications with the receivers using the IDs such that communications with receivers connected with adjacent ones of the transmitter coils do not interfere with each other.