A power contact EoL predictor includes a pair of terminals adapted to be connected to a set of switchable contact electrodes of a power contact; a power switching circuit configured to trigger activation of the contact electrodes based on a first logic state signal or deactivation based on a second logic state signal; a contact separation detector determining a time of separation of the switchable contact electrodes of the power contact during the deactivation, and a controller configured to generate the second logic state signal to trigger the deactivation, and determine a stick duration associated with the set of switchable contact electrodes. The stick duration is based on a difference between a time the second logic state signal is generated and the time of separation during the contact cycle. The controller generates an EoL prediction for the contact electrodes based on the determined stick duration for multiple contact cycles.

Provided are integrated circuits that include one or more magnetic tunnel junction ring oscillator(s) with tunable frequency and methods for operating the same. Accordingly, an integrated circuit is provided that includes a ring oscillator. The ring oscillator includes an input voltage terminal, an output voltage terminal, and an odd number of at least three inverters disposed electrically in series with one another between the input voltage terminal and the output voltage terminal. Each of the at least three inverters includes an NMOS transistor and one or more magnetic tunnel junctions (MTJs) disposed electrically in series with the NMOS transistor. The NMOS transistor of each of the at least three inverters is selectively tunable with regard to either or both of its threshold voltage and its effective channel width.

Provided are integrated circuits that include one or more magnetic tunnel junction ring oscillator(s) with tunable frequency and methods for operating the same. Accordingly, an integrated circuit is provided that includes a ring oscillator. The ring oscillator includes an input voltage terminal, an output voltage terminal, and an odd number of at least three inverters disposed electrically in series with one another between the input voltage terminal and the output voltage terminal. Each of the at least three inverters includes an NMOS transistor and one or more magnetic tunnel junctions (MTJs) disposed electrically in series with the NMOS transistor. The NMOS transistor of each of the at least three inverters is selectively tunable with regard to either or both of its threshold voltage and its effective channel width.

Provided are integrated circuits that include one or more magnetic tunnel junction ring oscillator(s) with tunable frequency and methods for operating the same. Accordingly, an integrated circuit is provided that includes a ring oscillator. The ring oscillator includes an input voltage terminal, an output voltage terminal, and an odd number of at least three inverters disposed electrically in series with one another between the input voltage terminal and the output voltage terminal. Each of the at least three inverters includes an NMOS transistor and one or more magnetic tunnel junctions (MTJs) disposed electrically in series with the NMOS transistor. The NMOS transistor of each of the at least three inverters is selectively tunable with regard to either or both of its threshold voltage and its effective channel width.

Provided are integrated circuits that include one or more magnetic tunnel junction ring oscillator(s) with tunable frequency and methods for operating the same. Accordingly, an integrated circuit is provided that includes a ring oscillator. The ring oscillator includes an input voltage terminal, an output voltage terminal, and an odd number of at least three inverters disposed electrically in series with one another between the input voltage terminal and the output voltage terminal. Each of the at least three inverters includes an NMOS transistor and one or more magnetic tunnel junctions (MTJs) disposed electrically in series with the NMOS transistor. The NMOS transistor of each of the at least three inverters is selectively tunable with regard to either or both of its threshold voltage and its effective channel width.

A pulsed power circuit (30, 31, 32) including an inductor (55) having a hybrid core of a switch magnetic material arranged and selected to function as a magnetic switch a damping magnetic material arranged and selected to damp energy reflections without interfering with the switch magnetic material functioning as a magnetic switch so that the circuit can mitigate resonances caused by reflected energy without any significant degradation of its switching function as part of an saturable reactor inductor.

A pulsed power circuit (30, 31, 32) including an inductor (55) having a hybrid core of a switch magnetic material arranged and selected to function as a magnetic switch a damping magnetic material arranged and selected to damp energy reflections without interfering with the switch magnetic material functioning as a magnetic switch so that the circuit can mitigate resonances caused by reflected energy without any significant degradation of its switching function as part of an saturable reactor inductor.

A magnetic momentum transfer generator utilizes three or more magnets aligned with each other. A first control magnet is positioned outside a coil. A second magnet is positioned within the windings of the coil and a third magnet is positioned on the opposite side of the coil opposite the control magnet. When the control magnet rotated or moved, mutual magnetic flux lines generated by all three magnets and passing through the coil winding are aligned at right angles to the coil, thereby inducing a maximum voltage at the terminals. This generator is particularly useful for short burst radio micro-transmitters that can be used for battery-less and wireless switching applications.

A magnetic momentum transfer generator utilizes three or more magnets aligned with each other. A first control magnet is positioned outside a coil. A second magnet is positioned within the windings of the coil and a third magnet is positioned on the opposite side of the coil opposite the control magnet. When the control magnet rotated or moved, mutual magnetic flux lines generated by all three magnets and passing through the coil winding are aligned at right angles to the coil, thereby inducing a maximum voltage at the terminals. This generator is particularly useful for short burst radio micro-transmitters that can be used for battery-less and wireless switching applications.

An example electrical power system includes a bus current controller configured to adjust a direct current (DC) provided on a DC bus, and a plurality of energy storage modules (ESMs). Each ESM includes at least one energy storage device, and includes a DC/DC converter configured to control charging of the at least one energy storage device from the DC bus and discharging of the at least one energy storage device onto the DC bus. A shared system controller is configured to control the bus current controller and the plurality of DC/DC converters. A method of controlling an electrical power system is also disclosed.