An overcurrent detector with an electric line and a sensor for monitoring an electric current in the line and outputting a measurement signal, and an integral-unit adapted to integrate an interval of consecutive values of the measurement signal and outputting an integrator-signal, the detector comprises a comparator unit for comparing a value of the integrator-signal with a threshold level and outputting a trigger signal, with the detector further comprises a threshold level determination unit, an input being connected to the sensor for receiving an actual measurement signal, and with an output being connected to the comparator unit, proving the comparator unit with the threshold level, and that the threshold level determination unit is adapted to determine the threshold level in dependence on the value of the actual measurement signal.

An apparatus includes a memory and a hardware processor communicatively coupled to the memory. The hardware processor receives, from a plurality of power supplies, a plurality of indications of electrical power disturbances detected by the plurality of power supplies and determines locations of the plurality of power supplies based on the plurality of indications. The hardware processor also determines, based on the plurality of locations, an event that caused the electrical power disturbances and classifies the event based on the location of the plurality of power supplies.

A method and a device for testing a battery state determines if a battery is faulty. A first impedance test is conducted to determine the internal resistance of the battery, wherein the battery is energized with an electrical current flow with a certain frequency and a resulting voltage response of the battery is measured. A load high-current test of the battery with a test pulse HRD test is conducted next. Then, a second impedance test is conducted. The measurement results of the tests are recorded and stored, and then evaluated by arranging such results offset in relation to one another, in such a way that the battery state can be derived therefrom, in particular whether the battery is faulty.

Provided is an electronic device and method for controlling the same, which controls an operation by detecting a voltage between a plurality of live terminals and thus determining whether there is an error in supplying power through a power input terminal. According to an embodiment, an electronic device includes a power input terminal including a plurality of live terminals and a neutral terminal; a voltage detection circuit connected between the plurality of live terminals for detecting a voltage between the plurality of live terminals; and a controller configured to control operation of the electronic device to be interrupted in response to a magnitude of the voltage between the plurality of live terminals smaller than a threshold.

Various embodiments relate to a detector circuit, including: a voltage source configured to produce a first voltage on a first output, a second voltage on a second output, and third voltage on a third output, wherein the first voltage is greater than the second voltage and the second voltage is greater than the third voltage; a first switch connected to the second output; a sampling capacitor connected to the switch, wherein the sampling capacitor is charged by the voltage source when the switch is closed; a first comparator with one input connected to the first output and a second input connected to the sampling capacitor; a second comparator with one input connected to the third output and a second input connected to the sampling capacitor; a multiplexer with a plurality of inputs configured to be connected to a plurality of terminals of an external circuit and an output connected to the sampling capacitor, the first input of the first comparator, and the first input of the second comparator; and a controller with inputs connected to the first comparator, the second comparator, and a clock generation unit, wherein the controller is configured to produce control signals to control the first switch and the multiplexer and wherein the controller is configured to produce an output signal indicting the presence of a current leak on one of the plurality of terminals.

A sensor includes a passage in a shield with a clear width of 25.2 to 32 mm, which provides a higher sensitivity to electrical differential current, and more particularly for determining the universal-current sensitive determination of an electric differential current. The sensor can be a part of a circuit breaker, a charging cable and a charging station.

The circuit breaker control module of the present disclosure comprises: a plurality of semiconductor switching units for blocking current flows of transmission distribution lines or performing switching operations so as to switch the current flow directions; a control unit for controlling the turn-on/turn-off operation of each semiconductor switching unit by transmitting a trip signal to each of the plurality of semiconductor switching units; and a plurality of insulation type signal transmission element units which are provided between the plurality of semiconductor switching units and the control unit such that the semiconductor switching units and the control unit are insulated, and which transmit the trip signal from the control unit to each of the plurality of semiconductor switching units, and thus the presently disclosed circuit breaker control module can reduce the risk of accidents due to an electrical arc and increase the stability and reliability of the control unit.

A computing device includes a power supply that supplies power to the computing device. The power supply includes a hardware processor that detects an electrical power disturbance in the power supply. The power supply also includes a bus that communicates an indication of the electrical power disturbance to a monitoring device. The indication includes an identifier of the power supply.

The present technology is to provide a detector capable of detecting an input voltage outside the guaranteed operating voltage range, even if the delay time caused in a logic element by a decrease in power-supply voltage varies due to an external factor. The detector includes a plurality of first detection circuits, a first detection rate calculation unit, a plurality of second detection circuits, a second detection rate calculation unit, and a comparison determination unit. Each of the plurality of first detection circuits detects whether or not an input voltage has a value outside a guaranteed operating range for a normal operation. The first detection rate calculation unit calculates a first detection rate of the detected number of the first detection circuits, and each of the plurality of second detection circuits detects whether or not a predetermined reference voltage is lower than a threshold voltage.

Techniques are described for controlling a sensing state of a device. In an example, a controller of the device stores, in a memory of the controller, first state data indicating a state of a sensor, the state being enabled. The controller, receives first input data indicating a request to disable the sensor. The controller determines that the sensor is enabled based at least in part on the first state data. Further, the controller causes the sensor to be disabled and stores, in the memory, second state data indicating that the sensor is disabled. The controller sends, to a processor, first output data indicating that the sensor is disabled.