A circuit includes an input for receiving power from an external power supply, a voltage regulator coupled to the power input and providing regulated voltage to an external circuit and to the power supply control circuit itself, and a first switch coupled between ground and an Enable input of the voltage regulator. A control input of the first switch is coupled to the regulated voltage, such that when the voltage regulator provides regulated voltage, the first switch is closed, coupling the Enable input to ground, keeping the voltage regulator active. A first switching circuit provides manual activation and deactivation of the voltage regulator; a second switching circuit provides automatic activation of the voltage regulator whenever the power input becomes powered. An intervening circuit prevents the second switching circuit from activating the voltage regulator when the first switching circuit has deactivated it, despite the continued presence of the external power supply.

A circuit includes an input for receiving power from an external power supply, a voltage regulator coupled to the power input and providing regulated voltage to an external circuit and to the power supply control circuit itself, and a first switch coupled between ground and an Enable input of the voltage regulator. A control input of the first switch is coupled to the regulated voltage, such that when the voltage regulator provides regulated voltage, the first switch is closed, coupling the Enable input to ground, keeping the voltage regulator active. A first switching circuit provides manual activation and deactivation of the voltage regulator; a second switching circuit provides automatic activation of the voltage regulator whenever the power input becomes powered. An intervening circuit prevents the second switching circuit from activating the voltage regulator when the first switching circuit has deactivated it, despite the continued presence of the external power supply.

A wireless power transmitter includes: a current adjuster configured to convert an input power into a transmission current, which is periodically varied according to a transmission frequency; and a power transmitter configured to receive the transmission current and wirelessly transmit power according to the transmission frequency.

There are provided methods, devices, and systems relating to discharging thyristor-switched capacitors. For example, there is provided a method for discharging the capacitors of a thyristor-switched capacitor (TSC) device coupled to a transmission line. The method can include determining whether an angle of a voltage on the transmission line is within one of a first threshold range and a second threshold range. Further, the method can include discharging the capacitors, when the angle is within the first threshold range, by operating the TSC device in a first discharging mode. Furthermore, the method can include discharging the capacitors, when the angle is within the second threshold range, by operating the TSC device in a second discharging mode distinct from the first discharging mode.

Power distribution apparatus with input and output power sensing and a method of use. A power distribution unit includes a sensor that senses power parameters of power outputs and a power input, a processor, and a communication circuit. A power management system includes a power manager, a user interface, and a plurality of power distribution units that may be located in one or more equipment cabinets and data centers. The system may compute apparent power, RMS power, power factor, energy usage over time, power usage history, or environmental history for any or all of the power distribution units. The system may identify an under-utilized server connected to one of the power distribution units and initiate a shut-down of that server.

Power distribution apparatus with input and output power sensing and a method of use. A power distribution unit includes a sensor that senses power parameters of power outputs and a power input, a processor, and a communication circuit. A power management system includes a power manager, a user interface, and a plurality of power distribution units that may be located in one or more equipment cabinets and data centers. The system may compute apparent power, RMS power, power factor, energy usage over time, power usage history, or environmental history for any or all of the power distribution units. The system may identify an under-utilized server connected to one of the power distribution units and initiate a shut-down of that server.

An integrated circuit structure including a reference circuit and at least two core circuits is provided. The reference circuit provides a reference current. The at least two core circuits are coupled to the reference circuit for receiving the reference current. Each of the core circuits includes a current-calibration circuit. The current-calibration circuit generates a bias current according to the reference current in the core circuit. The core circuits use the bias current to replace the reference circuit. In an IC test process, the reference circuit provides the reference current through the pin of the integrated circuit electronically connected to the external impedance. After the IC test process, the connection of the reference circuit and the pin of the integrated circuit is disconnected.

A device for providing a bandgap voltage reference. The device comprises a first switching circuit for providing a first temperature voltage which behaves proportionally to a present temperature, wherein the first switching circuit has two parallel current paths, first and second diode elements being respectively arranged in first and second current paths of the parallel current paths, a second switching circuit for providing a second temperature voltage which behaves in a complementary manner relative to the present temperature, a control circuit which is designed to control a voltage difference between the parallel current paths of the first switching circuit, and a current-bias circuit which is designed to control a ratio of a flow of current through the first diode element to a flow of current through the second diode element, the current-bias circuit comprising a calibration circuit which sets the ratio to a target value.

Embodiments include a resistor, coupled on a signal path, that includes one or more resistive memory elements, such as one or more magnetic tunnel junctions (MTJs). The resistance of the resistive memory elements may be digitally trimmable to adjust a resistance of the resistor on the signal path. The resistor may be incorporated into an analog or mixed signal circuit to pass an analog signal on the signal path. Other embodiments may be described and claimed.

In one aspect, a method includes protecting passive components connected to a high-frequency generator. In another aspect, a system includes a high-frequency generator having an HF source generating a high-frequency power signal at a fundamental frequency, and having a first control circuit which is fed with a signal related to an HF power transmitted by a high-frequency cable between the high-frequency generator and a load.