A semiconductor device including a plurality of power modules each of which includes a power semiconductor switching element that has a temperature detection diode, and a drive circuit that has an output circuit for switching on and off the power semiconductor switching element, and that outputs a warning signal for calling attention if the value of the forward voltage of the temperature detection diode becomes equal to or smaller than a first reference voltage value, and that outputs a protection operation signal for stopping the on/off operation of the power semiconductor switching element if the value of the forward voltage becomes equal to or smaller than a second reference voltage value smaller than the first reference voltage value. The semiconductor device outputs the logical sum of the warning signals of the individual power modules as an external warning signal.

An increase in the load of the booster circuit may be suppressed, and the voltage measurement accuracy may be improved. A battery monitoring IC of a battery monitoring system includes a first buffer amplifier and a second buffer amplifier driven by a power supply voltage or a boost voltage and having an input terminal connected to one terminal of any one of battery cells of an assembled battery. The control part selects the battery cell to be connected to the input terminals of the first and second buffer amplifiers. The control part switches a voltage for driving the first and second buffer amplifiers to the boost voltage when an upper battery cell is selected, and switches the voltage for driving the first and second buffer amplifiers to the power supply voltage when a battery cell other than the upper battery cell is selected.

The present disclosure relates to voltage sensing mechanisms. One example embodiment includes a voltage-measurement device. The voltage-measurement device includes a housing. The voltage-measurement device also includes an extendible gripper configured to be removably attached to a wire under test. Additionally, the voltage-measurement device includes at least one power supply. Further, the voltage-measurement device includes a power management chip electrically coupled to the at least one power supply and configured to manage a range of input voltages from the at least one power supply. The power management chip comprises a synchronous boost voltage regulator. Additionally, the voltage-management device has a microprocessor electrically coupled to the power management chip and the extendible gripper. The microprocessor is configured to receive electrical power from the power management chip. The microprocessor is also configured to receive an electrical signal from the extendible gripper indicative of a voltage associated with the wire under test.

The present disclosure provides an abnormal voltage monitoring device, a storage device, and a vehicle. The abnormal voltage monitoring device comprises a voltage divider configure to receive an input voltage from a voltage generator and output a first distribution voltage based on the input voltage, a second bandgap reference generation circuit configured to output a reference voltage, and a monitoring circuit configured to receive the first distribution voltage from the voltage divider and the reference voltage from the second bandgap reference generation circuit, and output an alarm signal responsive to comparing a voltage level of the first distribution voltage with that of the reference voltage. The voltage generator comprises a first bandgap reference generation circuit, and the second bandgap reference generation circuit is configured to generate the reference voltage differently than the first bandgap reference generation circuit.

A voltage comparator and an operation method thereof are provided. The voltage comparator includes an amplifying circuit, a reference current source, and a transient current source. A first input terminal and a second input terminal of the amplifying circuit respectively receive a first corresponding voltage corresponding to a target voltage and a reference voltage. The reference current source is coupled to the amplifying circuit to provide a reference current. The transient current source is coupled to the amplifying circuit to selectively provide a transient current. The transient current source detects a transition of a second corresponding voltage corresponding to the target voltage to dynamically adjust the transient current. Therefore, when a rapidly increasing voltage occurs in the target voltage, the transient current source may temporarily increase the current of the amplifying circuit, thereby accelerating the response speed of the amplifying circuit.

A vehicle, and a balancing device and method of controlling a state of charge of a reference electrode in a battery. The balancing device includes a measurement circuit and a charging circuit. The measurement circuit is configured to obtain a measurement of a reference voltage of the reference electrode. The charging circuit is configured to adjust the reference voltage based on the measurement. The state of charge of the reference electrode is controlled based on the reference voltage.

A power detection circuit is provided. The power detection circuit includes a comparator circuit operative to generate an output signal in response to an input signal. The output signal is configured to change from a first value to a second value in response to the input signal attaining a first threshold value. The output signal is configured to change from the second value to the first value in response to the input signal subsequently attaining a second threshold value. A current limiting circuit is connected to the comparator circuit and operative to limit a leakage current of the comparator circuit.

Circuitry for measuring a characteristic of an electrochemical cell, the circuitry comprising: a comparator having a first comparator input, a second comparator input and a comparator output; a feedback path between the comparator output and the second comparator input configured to provide a feedback signal to the second comparator input; and a loop filter configured to apply filtering to the feedback path to generate the feedback signal, wherein the loop filter comprises the electrochemical cell.

Disclosed is an electronic device is provided. The electronic device includes a first substrate, a second substrate arranged to be spaced apart from the first substrate, a first cable electrically connecting a first point on the first substrate and a second point on the second substrate, and a second cable electrically connecting a third point on the first substrate and a fourth point on the second substrate. The first substrate may include a first communication circuit, a second communication circuit, a detection circuit, a voltage application unit, and a ground unit, and a second substrate may include a first antenna, a first capacitive element, a second antenna, a second capacitive element, and an isolation circuit. The isolation circuit may isolate a radio frequency (RF) signal between the first path and the second path, and electrically connect the detection circuit to the ground unit through the first cable and the second cable.

A packaged current sensor integrated circuit includes a primary conductor having an input portion and an output portion configured to carry a current to be measured by one or more magnetic sensing elements supported by a semiconductor die adjacent to the primary conductor. A method of fabricating the packaged current sensor integrated circuit includes partially encasing the lead frame in a first mold material, applying an insulator to one or more die attach pads, attaching a die to the insulator, electrically connecting the die to secondary leads, and providing a second mold to the subassembly. The package is configured to provide increased voltage isolation.