A battery device and a battery protection method for same are provided. It is determined, according to electrical capacity of a battery, whether a battery device communicates with an electronic device, and whether the battery is being charged or discharged, whether to control the battery device to enter a shutdown mode.

An aspect relates to an apparatus including a first pair of switching devices configured to selectively couple an application processor to a Universal Serial Bus (USB) differential data transmission lines; a USB host port connector coupled to the USB differential data transmission lines; a second pair of switching devices configured to selectively couple an audio circuit to the USB differential data transmission lines; and an equalizer including differential terminals coupled to the USB differential data transmission lines, respectively.

A smart ring charging system comprises a charging source integrated into an object, the object configured to be held by a user wearing a smart ring. The smart ring may include a ring-shaped housing and a power source disposed within or at the ring-shaped housing and configured to receive energy from the charging source while the user is wearing the smart ring and holding the object. A controller may be disposed within or at the ring-shaped housing, or at the object with the charger and configured to estimate a charging rate at which the power source receives the energy from the charging source. The system may further include one or more indicators configured to indicate the charging rate.

Provided herein are system, methods and apparatuses for controlling replaceable rechargeable batteries powering and an electric vehicle, comprising, receiving battery utilization instructions computed by a remote battery management system for using and/or recharging each of a plurality of replaceable rechargeable batteries installed in an electric vehicle for powering the electric vehicle, and controlling one or more switching circuits configured to electrically couple or de-couple each of the plurality of batteries to each other and/or to an engine of the electric vehicle according to the received battery utilization instructions to use and/or recharge the respective battery.

Described herein is a battery system that allows a battery pack to operate in different modes at different times. Each of the different modes may provide its own set of functionality that affects how the battery pack operates and/or reacts to external input signals. A mode may change how the battery pack discharges power by, for example, altering whether terminals are enabled or disabled. A mode may change how the battery pack's hardware operates by, for example, disabling or enabling portions of the battery pack's hardware. A mode may change what battery-related services are provided by the battery pack and available to an end user by, for example, enabling or disabling the sending of battery status information from the battery pack.

The present solution can execute a handshake process to establish a bidirectional session utilizing communications that can be implemented on EVs and chargers from various manufacturers. The present solution relates to a charger that can execute a handshake process communication between the charger and an electric vehicle to establish a session for bidirectional power delivery between the charger and the electric vehicle via a power cable. The charger can transmit, in the handshake process to the electric vehicle, a data structure comprising a field for a minimum current with a value for the field that is less than zero. The charger can configure, subsequent to transmission of the data structure comprising the value for the minimum current, the session for bidirectional power delivery between the charger and the electric vehicle via the power cable.

A method for controlling power transfer from a grid to a rechargeable energy storage system, RESS, and/or an auxiliary load of the vehicle, via at least one intermediate power transfer component. The method comprises providing predicted operational information of the vehicle, the predicted operational information comprising a connected time period in which the vehicle is connected to the grid, providing component data comprising power transfer characteristic of the intermediate power transfer component, the component data including at least the critical temperature limit of the intermediate power transfer component, transferring power from the grid to the RESS and/or from the grid to the auxiliary load of the vehicle according to a power transfer model, such that the temperature of the intermediate power transfer component is kept at least below the critical temperature limit.

An apparatus and a method for an aerosol generating device is described, the apparatus including a charging controller. The charging controller is configured to control charging of a battery using a power supply at a charging current dependent, at least in part, on power capabilities of the power supply.

An RFID device includes a case, an antenna, and a power receiving coil. The case includes a rotation mechanism. The antenna is provided in the case. The power receiving coil is provided in the case away from the antenna in an axial direction of the rotation mechanism. The power receiving coil is connected to a power receiving unit that charges a battery. The power receiving coil has a cylindrical shape.

A vehicle is a vehicle in which a mounted power storage is charged with electric power from a charging facility, the vehicle including a communication unit that obtains a first voltage value indicating an outputtable voltage value that can be outputted from the charging facility and a processing unit that transmits to the charging facility, a third voltage value which is equal to or smaller than the first voltage value as a maximum voltage of the power storage when a second voltage value indicating a maximum voltage value of the power storage is larger than the first voltage value.