A charge control method can include: in response to connection with a charge device, selecting a charge protocol; when the selected charge protocol is a universal fast charge specification, determining a charge control strategy matching the universal fast charge specification, and charging the charge device based on the charge control strategy.

A device having a function of simultaneously charging and backing up data is provided. The device includes a transmission interface, a power supply circuit, a storage circuit, and a main control circuit. The transmission interface is connected to an electronic device. The power supply circuit is configured to supply power to the electronic device to charge the electronic device. The storage circuit is configured to access data of the electronic device, or to provide data stored in the storage circuit to the electronic device. The main control circuit is connected to the transmission interface, the power supply circuit and the storage circuit. The main control circuit is configured to control the power supply circuit to supply the power to the electronic device and the storage circuit to back up the data simultaneously.

An example charging station can include a frame with bays and modular charging units. The modular charging units can include a connector, a locking mechanism, and an actuator. The actuator can include a member that is movable between a first position at which the member is not in physical contact with the locking mechanism and a second position at which the member is in physical contact with the locking mechanism.

A contactless power feeding device of an embodiment includes: a placement portion on which a plurality of carts including a device and a power receiving unit that receives power to be fed to the device is placed in a state of being arranged in one direction; a power transmitting unit that is provided at each of placement positions at which the cart is placed in the placement portion and transmits power to the power receiving unit by contactless power feeding; a lock unit that is provided at each of at least a first placement position at which a first cart in the one direction is placed and a second placement position at which a next cart is placed among the placement positions, and locks movement of the cart; and a control unit that controls an operation of the lock unit.

A portable communication device includes a touchscreen display, a wireless charging circuit, and one or more processors operatively coupled with the wireless charging circuit and configured to detect a touch contact with respect to the touchscreen display, while wireless charging is not performed using the wireless charging circuit, allow recognition of the touch contact having a first touch characteristic and a second touch characteristic as a user input with respect to the touchscreen display, and while the wireless charging is performed using the wireless charging circuit, allow recognition of the touch contact having the first touch characteristic as the user input with respect to the touchscreen display and refrain from recognizing the touch contact having the second touch characteristic as the user input with respect to the touchscreen display.

A method may include determining that an information handling system is placed on a wireless charging pad. The wireless charging pad is communicatively coupled to a wireless docking station. The method may further include receiving, at the wireless charging pad, a first unique identifier from the wireless docking station. A wireless dock connection is initiated between the wireless docking station and the information handling system in response to receiving the first unique identifier.

A contactless battery system includes a sealable dustproof and waterproof case that houses a battery unit and at least one wireless power transmission coupler connected to the battery unit. The at least one wireless power transmission coupler is disposed with respect to at least one face of the sealable case to enable magnetic inductive signaling for charging, discharging, and communication with the battery.

Without physical contacts, the battery is inherently safe since voltage and current are not available to the touch. The lack of physical contacts also means that contact wear is eliminated and the battery modules have the benefit of inherent galvanic isolation. Since the battery system is sealed, internal intrusion detection systems may be used to detect improper attempts at battery changes or attacks on the electronics containing the usage and charging records in an attempt to increase the battery unit's value on the secondary battery market.

A charging controller carries out charging control of a power storage mounted on a vehicle. The vehicle includes a DC charging inlet. The charging controller carries out first charging control when a charging cable which is not a prescribed charging cable is connected to the DC charging inlet and carries out second charging control when the prescribed charging cable is connected to the DC charging inlet. For example, a time period for ground fault detection carried out during charging of the power storage is set differently between first charging control and second charging control. Alternatively, a response delay margin of a charging command is set differently between first charging control and second charging control.

An aerosol delivery device includes a receptacle configured to receive a substrate configured to carry an aerosol precursor composition, and a resonant transformer including a transmitter coupling device and a resonant receiver coupling device that is positioned in proximity to the substrate when received in the receptacle. The aerosol delivery device also includes a pulse width modulation (PWM) inverter configured to drive the resonant transformer. The PWM inverter includes a bridge circuit coupled to the transmitter coupling device, and a PWM controller embodied as an integrated circuit and configured to output a PWM signal to the bridge circuit configured to drive the transmitter coupling device to generate an oscillating magnetic field and induce an alternating voltage in the resonant receiver coupling device when exposed to the oscillating magnetic field. The alternating voltage causes the resonant receiver coupling device to generate heat and thereby vaporize components of the aerosol precursor composition.

A charging circuit applied to a first electronic device includes a charging interface, a charging module coupled therewith and configured to detect a connection between the charging interface and a second electronic device, and adjust a current output to the second electronic device, a reverse charging protocol module, and a control module. The reverse charging protocol module is configured to determine a reverse charging protocol matched with the charging current of the second electronic device. The control module is coupled with the charging module and the reverse charging protocol module, and configured to acquire the reverse charging protocol determined by the reverse charging protocol module in response to the connection between the charging interface and the second electronic device, and control the charging module to adjust the current output to the second electronic device based on the reverse charging protocol. The charging circuit can increase the reverse charging current.