A battery device includes a connection unit to which an electronic apparatus is connected, a calculation unit that calculates a remaining battery level of a battery of the battery device based on a full charge capacity of a battery of the electronic apparatus, and a display unit that displays information indicating a result of calculation made by the calculation unit.

A rechargeable battery short-circuit early detection device that detects a short-circuit in a rechargeable battery includes one or more processors connected to a current sensor that detects a charging current of the rechargeable battery, wherein the one or more processors are programmed to: if a detected temporal slope of the charging current exceeds a first threshold, determine that there is a possibility that a short circuit has occurred in at least one of the cells; detect anew a temporal slope of the charging current after a prescribed period of time has elapsed since the determination of said possibility; and thereafter, if the anew detected temporal slope of the charging current exceeds a second threshold that is greater than the first threshold, determine that there is a possibility that the short-circuit is progressing, and output a signal indicating said possibility.

A battery device in one aspect of the present disclosure comprises a battery, a cell voltage monitoring part, a power supply line, a plurality of monitor lines, and an interrupter. The interrupter interrupts the power supply line and all of the plurality of monitor lines when the battery enters an overdischarge state.

A device detects a deformation of an electrical energy store. The device has a measuring device which is designed to measure the electrical current/voltage behavior of the energy store, and an evaluation unit which is designed to detect a change in the current/voltage behavior and to determine the deformation on the basis of the change.

A processor-implemented battery management method includes: estimating state information of a plurality of battery cells in a battery pack using a first battery state estimation model; determining whether state information of at least one of the plurality of battery cells is to be estimated using a second battery state estimation model; and estimating the state information of the at least one battery cell using the second model, in response to a result of the determining being that the state information of the at least one battery cell is to be estimated using the second model.

An energy storage unit for a motor vehicle battery is provided, having an energy store, particularly configured as a battery cell module, for storing and delivering electric power. A measuring device measures electrical properties of the energy store. An evaluation unit, connected to the measuring device, ascertains the operational status of the energy store from the measurement results of the measuring device. An indicator unit is connected to the evaluation unit for depicting the operational status of the energy store. By ascertaining and depicting the operational status and not just the state of charge of the energy store, it is possible to dispense with separate complex measurements when fitting the energy store, so that an energy storage unit can be checked quickly and efficiently when fitted into a motor vehicle.

An electronic system and a charging method are provided. The electronic system includes an electronic device and a charger. The charger is coupled to the electronic device. The electronic device senses a first state of the electronic device. The electronic device determines whether a value corresponding to the first state is greater than a first threshold. When the value corresponding to the first state is greater than the first threshold, the electronic device provides a first control signal, and the charger charges the electronic device by using a first mode according to the first control signal. When the value corresponding to the first state is not greater than the first threshold, the electronic device provides a second control signal, and the charger charges the electronic device by using a second mode according to the second control signal.

A method and device for displaying SOC of a battery, and electronic equipment are provided. The method includes: an initial voltage and initial SOC of the battery are acquired; a current voltage and current SOC of the battery in a current state are acquired after charging or discharging the battery for a preset time; and if the ratio of the current voltage to the initial voltage meets a first preset condition and the ratio of the current SOC to the initial SOC meets a second preset condition, the current voltage and the current SOC are displayed.

This disclosure is directed to customizable charge status indicator systems for electrified vehicle charge port assemblies. Exemplary charge status indicator systems may include a charge port lighting module, and a human machine interface (HMI) that includes various user interfaces configured for receiving inputs for customizing different lighting effects that can be emitted by the charge port lighting module. The charge status indicator systems may further include a controller operably coupled to both the charge port lighting module and the HMI and configured for commanding the charge port lighting module to emit customized lighting effects in response to receiving input signals from the HMI.

An interactive logo includes a graphical mark, at least one property of the graphical mark, and a logo surface. The graphical mark is disposed on an enclosure of the electronic device to identify a company, an organization, or a brand. At least one property of the graphical mark changes corresponding to an amount of power remaining from a battery to power the electronic device.