A fault monitoring device may monitor and detect for faults corresponding to a high-side voltage rail, to low-side voltage rail, or internally within a voltage source connected to the high-side voltage rail and the low-side voltage rail. The fault monitoring device may determine sample voltage levels and/or sample resistance values to detect the faults. Also, in various embodiments, the fault monitoring device may perform one or more fault monitoring processes over multiple stages. The fault monitoring device may determine the sample voltage levels and/or the sample resistance values while switching a secondary resistance circuit in different states over the multiple stages.

A fault monitoring device may monitor and detect for faults corresponding to a high-side voltage rail, to low-side voltage rail, or internally within a voltage source connected to the high-side voltage rail and the low-side voltage rail. The fault monitoring device may determine sample voltage levels and/or sample resistance values to detect the faults. Also, in various embodiments, the fault monitoring device may perform one or more fault monitoring processes over multiple stages. The fault monitoring device may determine the sample voltage levels and/or the sample resistance values while switching a secondary resistance circuit in different states over the multiple stages.

In order to quickly and accurately diagnose the failure of a coupling capacitor of an earth leakage detection device, voltage output unit (11a, OP1) generates a periodically changing periodic voltage and applies the periodic voltage to the other end of coupling capacitor (Cc) via first resistor (R1). Second resistor (R2) and third resistor (R3) are connected in series between a connection point between coupling capacitor (Cc) and first resistor (R1), and a predetermined fixed potential. Voltage measurement unit (11b) measures a voltage at a voltage dividing point between second resistor (R2) and third resistor (R3). Diagnosis unit (11d) determines whether or not coupling capacitor (Cc) is normal based on a voltage measured when switch (MRp, MRm, MRpp) is turned on in a state where voltage output unit (11a, OP1) outputs a fixed voltage.

An electricity meter includes a front circuit connected to an external transformer and a conductor connected to the external transformer via the front circuit; a test circuit including a test generation chain and a test measuring chain connected to the conductor and a processing component; the test generation chain being arranged to apply a test voltage on the conductor, which produces a test current circulating in the test measuring chain, the test voltage having a level which depends on the impedance of the external transformer, the processing component being arranged to detect a cutoff of the external transformer when the level of the test voltage is greater than a predefined detection threshold.

Aspects of the present disclosure provide for a circuit. In at least some examples, the circuit includes an output node at which a voltage for transmission via a differential conductor is present. The circuit further includes a first pull-up network coupled between a voltage supply node and the output node and configured to include a first amount of resistance. The circuit further includes a second pull-up network coupled between a voltage supply node and the output node and configured to include a second amount of resistance. The circuit further includes a comparator having a first input terminal coupled to the output node, a second input terminal configured to receive a reference voltage, and an output terminal configured to output a comparison result.

The present invention relates to an aerosol generator that vaporizes a liquid type inhalation material, and more particularly, to a circuit capable of sensing and controlling a heater voltage, without being affected by power of a battery, in an aerosol generator using a liquid cartridge. According to the present invention, there is provided a circuit for sensing and controlling a heater voltage in an aerosol generator, the circuit including: a battery that supplies power; a microcontroller; a first FET connected to the battery and turned on/off according to a sensing control signal output from the microcontroller; a sensing resistor connected to the first FET; a second FET connected to the battery and turned on/off according to a heater control signal output from the microcontroller; and a heater resistor connected to the second FET and also connected to one end of the sensing resistor, wherein the upstream end of the sensing resistor is connected to the microcontroller, and the downstream end of the sensing resistor has one side connected to the microcontroller and the other side connected to the second FET.

A current measuring system for measuring current from a conductor comprises a first and second circuit and a current measurer connected to a conductor connected to a first power source. The first circuit comprises an inverting operational amplifier, which generates a first threshold signal when current flows into the first power source. The second circuit comprises a biasing circuit and a non-inverting operational amplifier, which generates the first threshold signal at the second output when current flows out of the first power source.

Provided is an overcurrent detection circuit for detecting an overcurrent flowing upon turning on of a switching element, the overcurrent detection circuit including a main current detection unit configured to detect whether an input signal according to a main current is higher than or equal to a set detection threshold, and a condition control unit configured to control at least one of a waveform of the input signal in the main current detection unit or the detection threshold to control a comparison condition in the main current detection unit, in which the condition control unit is configured to set the comparison condition to a first condition during a period from the turning on of the switching element until elapse of a first period, and set the comparison condition to a second condition during a period from the elapse of the first period until elapse of a second period.

A voltage level detector includes a voltage divider that generates a first division voltage and a second division voltage. A first comparator compares any one of the first and second division voltages with a reference. A second comparator compares the other of the first and second division voltages with the reference. A first switch converts a connection path between the first and second division voltages and the first and second comparators based on a clock signal. A determination circuit determines, based on a first comparison signal and a second comparison signal, whether the voltage level detector is normal. A second switch converts a connection path between the first and second comparison signals and input terminals of the determination circuit based on the clock signal.

A power delivery system includes a power sourcing equipment, a powered device and a transmission cable. When the power sourcing equipment is electrically connected to the powered device via the transmission cable, an over-current detecting circuit in the power sourcing equipment is configured to detect over-current occurrence of the powered device. Meanwhile, the power sourcing equipment is configured to determine the functionality of the over-current detecting circuit based on its specific pin and provide single fault protection when the over-current detecting circuit fails.