A multifunctional battery health state detection device is disclosed, which includes a housing, two ignition clamps for connecting to a vehicle battery; a microcontroller; a sampling circuit connected to the two ignition clamps for sampling a voltage signal of the vehicle battery; and an indicator unit including a plurality of indicators configured to display a ranking of the battery health state of the vehicle battery. The microcontroller is configured to obtain the sampled voltage signal from the sampling circuit, detect the ranking of the battery health state based on the sampled voltage signal, and control the indicator unit to display the battery health state according to the ranking of the battery health stat, and boost the vehicle battery by providing starting energy from a portable power supply to the vehicle battery in response to detecting the battery health state being one of two lowest rankings among a plurality of rankings.

The battery system includes a secondary battery, a voltage sensor, a current sensor, a temperature sensor, and a processor. The processor is configured to calculate a polarization overvoltage by subtracting a voltage drop amount caused by a DC resistance and a reactive resistance of the secondary battery determined in accordance with a temperature and an SOC of the secondary battery from a voltage difference between OCV and CCV of the secondary battery.

An electronic apparatus, an input apparatus and a method of determining a remaining utility of a battery of the same, the electronic apparatus including: a battery configured to supply power to the electronic apparatus; a first detector configured to receive a voltage value of the battery, to convert the voltage value into a signal, and to output the signal; a second detector configured to detect a decrease in the voltage value of the battery to a reference voltage or lower and to output a detection result; and a controller configured to receive the output values of the first and second detectors, to determine a remaining utility of the battery based on the output values of the first and second detectors, and to determine an abnormal state of the battery based on the output values of the first and second detectors.

A provisioning device includes a communication module capable of communicating with a plurality of battery management systems included in the battery pack; and a processor, wherein the processor causes the communication module to wirelessly transmit a provisioning signal for switching at least one battery management system of the plurality of battery management systems to a provisioning mode, receives state information of the battery and the battery management system from the plurality of battery management systems through the communication module, and assigns an ID of a network of the battery pack and an ID of each of the battery management system based on the state information of the battery management system received through the communication module.

A power tool includes: a rechargeable battery; a motor; a drive circuit; an operation unit; a battery state detection circuit; a control circuit; and an interruption circuit. The battery state detection circuit detects a battery voltage, and when the detected battery voltage is lower than or equal to a prescribed voltage, the battery state detection circuit outputs a low-voltage signal. The control means outputs a control signal to the drive circuit instructing to drive the motor when the operation unit is operated and halts the output of the control signal to the drive circuit instructing to halt driving the motor in response to the low-voltage signal. The interruption circuit outputs an interruption signal to the drive circuit in response to the low-voltage signal to thereby interrupt the drive circuit and halt driving the motor irrespective of whether or not the control signal is outputted to the drive circuit.

The disclosed embodiments provide a system that monitors a battery in a portable electronic device. During operation, the system monitors a state of charge of the battery while the battery is powering the portable electronic device. Next, when the state of charge of the battery reaches a predetermined reserve capacity, the system monitors a voltage of the battery. Then, when the monitored voltage of the battery reaches a predetermined termination voltage, the system puts the portable electronic device into a low power usage state.

A method for displaying a terminal charging status and a terminal. The method includes: displaying a charging status region on a terminal screen when it is detected that a terminal battery is being charged, with a halo enlarging or shrinking with a preset frequency existing at the edge of the charging status region; according to a ratio of the current electric quantity of the terminal battery to the electric quantity of the terminal battery being fully charged, displaying a filled region having the same ratio in the charging status region. The method for displaying a terminal charging status and the terminal can realize visually displaying a charging status and a charging progress of the terminal.

A refuse vehicle includes a chassis, a body assembly coupled to the chassis, the body assembly defining a refuse compartment, an electric energy system configured to store power and supply power to at least one of the chassis or the body assembly, and a power control system. The power control system is configured to measure one or more electrical attributes of at least one of the chassis and the body assembly and determine a power profile for at least one of the chassis and the body assembly, the power profile describing, based on a remaining power of the electric energy system, at least one of a length of time the refuse vehicle can continue to operate or a distance that the refuse vehicle can traverse. the power control system is further configured to control a function of a non-essential component of the refuse vehicle based on the power profile.

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.

Provided are a battery pack and a method of controlling the same, in which the battery pack includes a battery module supplying power to a load, a voltage measuring unit measuring a voltage of the battery module, a current measuring unit measuring a current output to the load from the battery module, and a control unit determining whether a cause of an error occurring in the load is the load or the battery pack, based on whether a warning signal corresponding to the voltage of the battery module is generated and whether a current value measured by the current measuring unit for a specific time period satisfies a current profile of the load.