Examples described herein relate to modular power supply unit. The modular power supply unit may include an output connector through which the modular power supply unit is removably connectible to a host circuit board. The output connector includes ID pins to receive signals indicative of a power demand corresponding to the host circuit board. Further, the modular power supply unit may include a voltage regulator to output an electrical power at a plurality of power settings. Moreover, the modular power supply unit may include control unit coupled to the output connector and the voltage regulator. The control unit may determine a power demand code based on the signals received at the one or more ID pins; identify a power setting, from the plurality of power settings, based on the determined power demand code; and cause the voltage regulator to generate the electrical power at the identified power setting.

Examples described herein relate to modular power supply unit. The modular power supply unit may include an output connector through which the modular power supply unit is removably connectible to a host circuit board. The output connector includes ID pins to receive signals indicative of a power demand corresponding to the host circuit board. Further, the modular power supply unit may include a voltage regulator to output an electrical power at a plurality of power settings. Moreover, the modular power supply unit may include control unit coupled to the output connector and the voltage regulator. The control unit may determine a power demand code based on the signals received at the one or more ID pins; identify a power setting, from the plurality of power settings, based on the determined power demand code; and cause the voltage regulator to generate the electrical power at the identified power setting.

Presented herein are methodologies for providing power for last gasp operations of a circuit board when power is unexpectedly interrupted. A method includes monitoring a voltage of a main power supply; when the voltage of the main power supply falls below a predetermined threshold, disabling a first point of load (POL) converter that is being powered by the main power supply; boosting a voltage of an output capacitor of the first point of load converter to obtain a boosted voltage; and supplying the boosted voltage to an input of a second point of load converter.

Presented herein are methodologies for providing power for last gasp operations of a circuit board when power is unexpectedly interrupted. A method includes monitoring a voltage of a main power supply; when the voltage of the main power supply falls below a predetermined threshold, disabling a first point of load (POL) converter that is being powered by the main power supply; boosting a voltage of an output capacitor of the first point of load converter to obtain a boosted voltage; and supplying the boosted voltage to an input of a second point of load converter.

A voltage regulator circuit is provided. The voltage regulator circuit includes a voltage regulator configured to provide an output voltage at an output terminal. A plurality of macros are connectable at a plurality of connection nodes of a connector connected to the output terminal of the voltage regulator. A feedback circuit having a plurality of feedback loops is connectable to the plurality of connection nodes. The feedback loop of the plurality of feedback loops, when connected to a connection node of the plurality of connection nodes, is configured to provide an instantaneous voltage of the connection node as a feedback to the voltage regulator. The voltage regulator is configured, in response to the instantaneous voltage, regulate the output voltage to maintain the instantaneous voltage of the connection node approximately equal to a reference voltage.

A voltage regulator circuit is provided. The voltage regulator circuit includes a voltage regulator configured to provide an output voltage at an output terminal. A plurality of macros are connectable at a plurality of connection nodes of a connector connected to the output terminal of the voltage regulator. A feedback circuit having a plurality of feedback loops is connectable to the plurality of connection nodes. The feedback loop of the plurality of feedback loops, when connected to a connection node of the plurality of connection nodes, is configured to provide an instantaneous voltage of the connection node as a feedback to the voltage regulator. The voltage regulator is configured, in response to the instantaneous voltage, regulate the output voltage to maintain the instantaneous voltage of the connection node approximately equal to a reference voltage.

A current booster circuit, which can be coupled between a gate driver and a power switch, includes controlled current sources and current sensors to provide a scaled copy of the booster input current at the booster output while operating in a current-gain mode during on-to-off or off-to-on switching periods. During switched-on or switched-off periods, the booster can pull the output to the high or low rail, respectively, through low-impedance circuitry to hold the switch on or off. A voltage and/or current feedback path between the booster output and the booster input permits the booster to control the voltage input during switching operation. The current booster devices and methods can be compatible with both smart and conventional gate drivers of either the voltage-driven or current-driven variety.

A current booster circuit, which can be coupled between a gate driver and a power switch, includes controlled current sources and current sensors to provide a scaled copy of the booster input current at the booster output while operating in a current-gain mode during on-to-off or off-to-on switching periods. During switched-on or switched-off periods, the booster can pull the output to the high or low rail, respectively, through low-impedance circuitry to hold the switch on or off. A voltage and/or current feedback path between the booster output and the booster input permits the booster to control the voltage input during switching operation. The current booster devices and methods can be compatible with both smart and conventional gate drivers of either the voltage-driven or current-driven variety.

The present disclosure uses a capacitive voltage divider to supply a voltage that can be more readily handled by main-stream semiconductor and magnetic components (generally less than 1000 volts). The divided system voltage, expected to be between 500 and 1000 volts, is then converted to a power supply voltage to be used by the measuring equipment. For safety reasons, this voltage is frequently required to be less than approximately 50 volts if it is delivered via a connectorized cable with exposed contacts.

An integrated circuit has a CMOS signal path coupled for receiving a data signal. A compensation circuit is coupled to a power supply rail of the CMOS signal path for injecting a compensation current into the power supply rail. The compensation circuit can be a charge pump operating in response to the data signal to inject the compensation current into the power supply rail each transition of the data signal. The compensation circuit can be a replica CMOS signal path to inject the compensation current into the power supply rail each transition of the data signal. The compensation circuit can be a voltage regulator and current mirror including an input coupled to the voltage regulator. The replica CMOS signal path receives an operating potential from the voltage regulator. An output of the current mirror injects the compensation current into the power supply rail each transition of the data signal.