A wireless charging device (20) and a to-be-charged device (10) are provided, to support two or more wireless charging technologies, so as to optimize a circuit design and improve power transmission efficiency. The to-be-charged device (10) includes: a first receiving coil, configured to receive an electromagnetic signal based on a first wireless charging technology, and convert the electromagnetic signal into an alternating current signal; and a second receiving coil, configured to receive an electromagnetic signal based on a second wireless charging technology, and convert the electromagnetic signal into an alternating current signal, where the first wireless charging technology and the second wireless charging technology support different resonance frequency ranges.

A wireless charging device (20) and a to-be-charged device (10) are provided, to support two or more wireless charging technologies, so as to optimize a circuit design and improve power transmission efficiency. The to-be-charged device (10) includes: a first receiving coil, configured to receive an electromagnetic signal based on a first wireless charging technology, and convert the electromagnetic signal into an alternating current signal; and a second receiving coil, configured to receive an electromagnetic signal based on a second wireless charging technology, and convert the electromagnetic signal into an alternating current signal, where the first wireless charging technology and the second wireless charging technology support different resonance frequency ranges.

a wireless charger, comprising: a top cover for placing an electronic device thereon; at least one coil, disposed under the top cover; and a first magnet embedded inside the top cover for aligning with a second magnet of the electronic device for wireless charging the electronic device.

a wireless charger, comprising: a top cover for placing an electronic device thereon; at least one coil, disposed under the top cover; and a first magnet embedded inside the top cover for aligning with a second magnet of the electronic device for wireless charging the electronic device.

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 an antenna. 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.

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 an antenna. 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.

Charging devices according to embodiments of the present technology may include a housing including an input configured to receive power from a power source and provide power to internal components of the charging device. The charging devices may include a ferrite. The ferrite may be coupled with electrical ground. The charging devices may also include a conductive coil seated in the ferrite. The conductive coil may be configured to generate an electromagnetic field from an AC signal.

The wireless charging circuit includes an oscillation circuit and a monitoring circuit that are sequentially connected. The oscillation circuit includes an excitation voltage source, a full-bridge circuit, and an LC series circuit that are connected in series. When damped oscillation occurs in the LC series circuit, the LC series circuit outputs a resonant voltage signal during damped oscillation to the monitoring circuit. The monitoring circuit includes a comparison module and a processing module. The comparison module is configured to receive the resonant voltage signal and convert the resonant voltage signal into a digital square wave signal. The processing module is configured to receive the digital square wave signal, obtain a quantity of peaks, a quantity of troughs, or a sum of the quantity of peaks and the quantity of troughs and that is in a resonant voltage attenuation waveform, determine a quality factor Q.

A circuit control apparatus includes: a charging control module, a circuit switching module, a capacitance detection module, a first change-over switch, and a first polar plate. The first change-over switch includes a first common terminal, a second terminal, and a third terminal. The first polar plate is electrically connected to the first common terminal. The charging control module is electrically connected to the second terminal. The capacitance detection module is electrically connected to the third terminal.

A circuit control apparatus includes: a charging control module, a circuit switching module, a capacitance detection module, a first change-over switch, and a first polar plate. The first change-over switch includes a first common terminal, a second terminal, and a third terminal. The first polar plate is electrically connected to the first common terminal. The charging control module is electrically connected to the second terminal. The capacitance detection module is electrically connected to the third terminal.