An electronic device and a method for overcurrent detection are disclosed herein. The electronic device causes a high-side offsetting voltage drop and converts a voltage difference between a first voltage at an input terminal of an upper-bridge power component of a power stage and a sum of a first balancing voltage drop and the high-side offsetting voltage drop into a first current. The electronic device further converts a voltage difference between a second voltage of an output terminal of the upper-bridge power component and a second balancing voltage drop into a second current, compares the first current and the second current, and generates a high-side overcurrent protection (OCP) signal with logic high for a driver of the power stage when the first current is stronger than the second current, such that the driver turns off the upper-bridge power component accordingly.

A driver includes a current generator having an input and first and second outputs. The current generator generates a first current at the first output while a signal at the input is at a first logic state and generates a second current at the second output while the signal at the input is at a second logic state. A comparator has a first comparator input, a second comparator input, and a first comparator output, and a second comparator output. The first comparator input is coupled to the first output, and the second comparator input is coupled to the second output. A latch has a first latch input, a second latch input, and a latch output. The first latch input is coupled to the first comparator output, and the second latch input is coupled to the second comparator output. A gate control circuit has an input coupled to the latch output.

A comparator is presented. The comparator includes an input port for receiving an input voltage; an output port for providing an output voltage; a resistive divider, first and second transistors, and a differential amplifier. The resistive divider has a first node for providing a first voltage and a second node for providing a second voltage. The first transistor has a control terminal coupled to the first node, a first terminal coupled to the input port, and a second terminal coupled to a common node. The second transistor has a control terminal coupled to the second node, a first terminal coupled to the input port, and a second terminal coupled to the common node. The differential amplifier has a first input coupled to the first terminal of the first transistor, a second input coupled to the first terminal of the second transistor and an output coupled to the output port.

In accordance with an embodiment, a circuit includes a plurality of comparators disposed on an integrated circuit, the plurality of comparators having inputs coupled to a monitored power supply line; and a voting circuit having inputs coupled to outputs of the plurality of comparators. An output of the voting circuit is configured to provide a signal indicative of a brown out condition of a power source coupled to the monitored power supply line.

In one aspect, an example method includes drawing a current through a doorbell circuit. While drawing the current through the doorbell circuit, the example method includes determining, by the doorbell device, a maximum doorbell circuit current that will not activate a doorbell chime. Based on determining the maximum doorbell circuit, the example method includes configuring a doorbell device to draw the determined maximum doorbell circuit current through the doorbell circuit. Determining the maximum doorbell circuit current that will not activate the doorbell chime further includes: (i) determining whether the current being drawn through the doorbell circuit has activated the doorbell chime, (ii) if the current being drawn through the doorbell circuit has activated the doorbell chime, decrementing the current drawn through the doorbell circuit, and (iii) if the current being drawn through the doorbell circuit has not activated the doorbell chime, incrementing the current drawn through the doorbell circuit.

An apparatus is provided for monitoring a high-voltage on-board power supply system of an electrically operated vehicle for the occurrence of overloading, wherein the high-voltage on-board power supply system includes as components one or more energy sources and/or one or more energy sinks which are each connected via a conductor line arrangement to a first supply potential line and to a second supply potential line. Each of the components is assigned a current sensor which is designed to detect a current flowing through the respective component and to transmit information representing the level of the current to an evaluation unit for evaluation. The evaluation unit is designed to compare the current with a first current threshold and a second current threshold and to output a switch-off signal at least for the component assigned to the current sensor if, as a first criterion, the level of the current and the duration of the level of the current are between the first and second current thresholds.

Systems and methods for verifying a reference voltage within a battery pack are disclosed. In one example, an assessment of a reference voltage is made via a band-gap voltage of a microcontroller. The system and method may be particularly useful determining whether or not the reference voltage has drifted from a desired voltage.

Embodiments of the present disclosure provide an electrical device, a method for controlling a solid state circuit breaker electrical device, and a computer-readable storage medium. The method comprises: in a closed state of a mechanical switch of the electrical device, closing one of a plurality of electronic switches of the electrical device within a predetermined time period before a zero-crossing point of an input voltage of a bus circuit to which the electrical device is connected; acquiring a current value or a voltage value of a sampling resistor in the electrical device within the predetermined time period; and in response to determining that the current value or the voltage value as acquired is less than or equal to a predetermined threshold, causing an indication component to indicate that there is no short circuit fault in the bus circuit. In this way, it is possible to effectively avoid repeated closing of electronic switches of the electrical device such as a solid state circuit breaker, thereby significantly extending the service life of electronic switches of the electrical device and thereby improving the service life and user experience of the electrical device.

A facility plan evaluation device includes a proposed plan receiving unit receiving input of a facility plan including capacities and locations of charging and discharging facilities to be newly arranged in a power system, a prediction unit predicting charge and discharge amounts of the charging and discharging facilities, and demands and power generation amounts of existing facilities, which are facilities already connected in the power system, a power flow calculating unit estimating voltage and current in the power system based on a prediction result of the prediction unit, a determination unit determining whether at least one of deviation of voltage from a proper range and overcurrent occurs based on an estimation result of the power flow calculating unit, and determining whether the facility plan needs to be modified based on a determination result, and a result presenting unit presenting a determination result of the determination unit.

A dual chemistry battery system is disclosed that preserves the voltage of the primary battery in a vehicle while connected in parallel to a secondary battery. The system utilizes batteries with different chemistry and voltage output characteristics to maintain at least the necessary charge in the primary battery for starting the vehicle. Preferred embodiments utilize a lithium-ion Auxiliary Power Unit (APU) to preserve the charge of the vehicle's primary lead acid battery.