In a power switching apparatus, a first switch includes a first end coupled to a first input terminal, a second end coupled to an output terminal, and a control end coupled to a second input terminal and coupled to a ground via a first resistor. A second resistor is coupled between the output terminal and the ground. A second switch includes a first end coupled to the second input terminal, a second end coupled to the output terminal and a control end coupled to the ground via a third resistor. A third switch includes a first end coupled to the control end of the second switch and the first end of the third resistor, a second end coupled to the first input terminal and a control end coupled to the second input terminal and coupled to the ground via the first resistor.

A system, method and apparatus for providing pulsed power comprises a trigger comprising a pulse generator and a photonic transmitter and a multi-stage switch comprising a gate driver circuit, the gate driver circuit further comprising a plurality of transistors connected in series and a plurality of driver stages wherein each of the transistors is turned on and off simultaneously by the plurality of driver stages.

A system, method and apparatus for providing pulsed power comprises a trigger comprising a pulse generator and a photonic transmitter and a multi-stage switch comprising a gate driver circuit, the gate driver circuit further comprising a plurality of transistors connected in series and a plurality of driver stages wherein each of the transistors is turned on and off simultaneously by the plurality of driver stages.

A radio frequency switch includes a control buffer circuit to generate a first gate voltage and a first body voltage; and a switching circuit to switch at least one signal path in response to the first gate voltage and the first body voltage. The control buffer circuit includes an off voltage detection circuit to detect whether the off voltage is a negative voltage or a ground voltage and output a voltage detection signal, a first gate buffer circuit to output a first gate voltage having a voltage level based on the voltage detection signal and the band selection signal, and a first body buffer circuit to output a first body voltage having a voltage level based on the voltage detection signal, the band selection signal, and the mode signal.

A radio frequency switch includes a control buffer circuit to generate a first gate voltage and a first body voltage; and a switching circuit to switch at least one signal path in response to the first gate voltage and the first body voltage. The control buffer circuit includes an off voltage detection circuit to detect whether the off voltage is a negative voltage or a ground voltage and output a voltage detection signal, a first gate buffer circuit to output a first gate voltage having a voltage level based on the voltage detection signal and the band selection signal, and a first body buffer circuit to output a first body voltage having a voltage level based on the voltage detection signal, the band selection signal, and the mode signal.

A microelectromechanical resonant switch (resoswitch) converts received radio frequency (RF) energy into a clock output. The resoswitch first accepts incoming amplitude- or frequency-shift keyed clock-modulated RF energy at a carrier frequency, filters it, provides power gain via resonant impact switching, and finally envelop detects impact impulses to demodulate and recover the carrier clock waveform. The resulting output derives from the clock signal that originally modulated the RF carrier, resulting in a local clock that shares its originator's accuracy. A bare push-pull 1-kHz RF-powered mechanical clock generator driving an on-chip inverter gate capacitance of 5 fF can potentially operate with only 5 pW of battery power, 200,000 times lower than a typical real-time clock. Using an off-chip inverter with 17.5 pF of effective capacitance, a 1-kHz push-pull resonator would consume 17.5 nW.

A microelectromechanical resonant switch (resoswitch) converts received radio frequency (RF) energy into a clock output. The resoswitch first accepts incoming amplitude- or frequency-shift keyed clock-modulated RF energy at a carrier frequency, filters it, provides power gain via resonant impact switching, and finally envelop detects impact impulses to demodulate and recover the carrier clock waveform. The resulting output derives from the clock signal that originally modulated the RF carrier, resulting in a local clock that shares its originator's accuracy. A bare push-pull 1-kHz RF-powered mechanical clock generator driving an on-chip inverter gate capacitance of 5 fF can potentially operate with only 5 pW of battery power, 200,000 times lower than a typical real-time clock. Using an off-chip inverter with 17.5 pF of effective capacitance, a 1-kHz push-pull resonator would consume 17.5 nW.

An embodiment device comprises a processing circuit and IP circuitry coupled to a power supply line, wherein the IP circuitry has an IP circuitry supply threshold for IP circuitry operation. A supply monitor circuit is coupled to the power supply line to sense the voltage on the power supply line and to switch the processing circuit to a low-power mode as a result of a drop in the voltage on the power supply line. The supply monitor circuit comprises a threshold setting node and is configured to be deactivated as a result of the voltage on the power supply line dropping below a deactivation threshold level set at the threshold setting node. A threshold setting circuit is configured to apply to the threshold setting node of the supply monitor circuit the IP circuitry supply threshold as a result of the processing circuit being in the low-power mode.

An embodiment device comprises a processing circuit and IP circuitry coupled to a power supply line, wherein the IP circuitry has an IP circuitry supply threshold for IP circuitry operation. A supply monitor circuit is coupled to the power supply line to sense the voltage on the power supply line and to switch the processing circuit to a low-power mode as a result of a drop in the voltage on the power supply line. The supply monitor circuit comprises a threshold setting node and is configured to be deactivated as a result of the voltage on the power supply line dropping below a deactivation threshold level set at the threshold setting node. A threshold setting circuit is configured to apply to the threshold setting node of the supply monitor circuit the IP circuitry supply threshold as a result of the processing circuit being in the low-power mode.

A pulse shaping device includes an inductor that is selectively output-coupled to a first port of a capacitor. The inductor is charged to a selected current throughput and then coupled to the first port to generate a first characteristic within the current flowing at a second port of the capacitor. The capacitor is charged until reaching a clamping voltage at the first port. A voltage clamp of the shaping device clamps the first port of the capacitor at the clamping voltage to generate a second characteristic within the current flowing at a second port of the capacitor.