An apparatus including a first circuit and a second circuit. The first circuit may generate an output signal with a regulated voltage and maintain a constant switch frequency having a first on time and a first off time. The second circuit may generate a shifted signal based on a phase delay with respect to the output signal and maintain a shifted frequency having a second on time and a second off time. The second on time may follow the first on time by the phase delay. The second on time may be based on the first on time and transient conditions of a load. The apparatus may implement an automatic phase shift adjustment. A current sensing comparison may implement a cycle-by-cycle comparison between the output signal and the shifted signal to determine the second on time and perform a tuning operation to achieve inductor current balancing.

An apparatus including a first circuit and a second circuit. The first circuit may generate an output signal with a regulated voltage and maintain a constant switch frequency having a first on time and a first off time. The second circuit may generate a shifted signal based on a phase delay with respect to the output signal and maintain a shifted frequency having a second on time and a second off time. The second on time may follow the first on time by the phase delay. The second on time may be based on the first on time and transient conditions of a load. The apparatus may implement an automatic phase shift adjustment. A current sensing comparison may implement a cycle-by-cycle comparison between the output signal and the shifted signal to determine the second on time and perform a tuning operation to achieve inductor current balancing.

An apparatus including a first circuit and a second circuit. The first circuit may generate an output signal with a regulated voltage and maintain a constant switch frequency having a first on time and a first off time. The second circuit may generate a shifted signal based on a phase delay with respect to the output signal and maintain a shifted frequency having a second on time and a second off time. The second on time may follow the first on time by the phase delay. The second on time may be based on the first on time and transient conditions of a load. The apparatus may implement an automatic phase shift adjustment. A current sensing comparison may implement a cycle-by-cycle comparison between the output signal and the shifted signal to determine the second on time and perform a tuning operation to achieve inductor current balancing.

An apparatus including a first circuit and a second circuit. The first circuit may generate an output signal with a regulated voltage and maintain a constant switch frequency having a first on time and a first off time. The second circuit may generate a shifted signal based on a phase delay with respect to the output signal and maintain a shifted frequency having a second on time and a second off time. The second on time may follow the first on time by the phase delay. The second on time may be based on the first on time and transient conditions of a load. The apparatus may implement an automatic phase shift adjustment. A current sensing comparison may implement a cycle-by-cycle comparison between the output signal and the shifted signal to determine the second on time and perform a tuning operation to achieve inductor current balancing.

A power multiplier and method are provided. The power multiplier includes a power multiplying network that is a multiply-connected, velocity inhibiting circuit constructed from a number of lumped-elements. The power multiplier also includes a launching network, and a directional coupler that couples the launching network to the power multiplying network. The power multiplier provides for power multiplication at nominal power generation frequencies such as 50 Hertz, 60 Hertz, and other power frequencies, in a compact circuit.

A power multiplier and method are provided. The power multiplier includes a power multiplying network that is a multiply-connected, velocity inhibiting circuit constructed from a number of lumped-elements. The power multiplier also includes a launching network, and a directional coupler that couples the launching network to the power multiplying network. The power multiplier provides for power multiplication at nominal power generation frequencies such as 50 Hertz, 60 Hertz, and other power frequencies, in a compact circuit.

A voltage regulator system, comprising: a switched capacitor (SC) regulator that operates at a switching frequency and receives an input voltage; and a controller configured to control an operation of the SC regulator by adjusting the switching frequency of the SC regulator based on efficiency. In some embodiments, the switching frequency is swept to determine a best efficiency. In some embodiments, the switching frequency is swept at each of a plurality of values for the input voltage. In some embodiments, the system includes further one or more switches in series with the SC regulator. In some embodiments, the SC regulator includes an output terminal that is coupled to a battery.

An energy harvester system includes an aircraft power cable carrying an alternating current and an energy harvester. The energy harvester includes a ferromagnetic ring encircling the aircraft power cable and configured so that the alternating current in the aircraft power cable generates magnetic flux in the ferromagnetic ring and an inductive coil wrapped around at least a portion of the ferromagnetic ring to generate a voltage from the magnetic flux in the ferromagnetic ring.

An energy harvester system includes an aircraft power cable carrying an alternating current and an energy harvester. The energy harvester includes a ferromagnetic ring encircling the aircraft power cable and configured so that the alternating current in the aircraft power cable generates magnetic flux in the ferromagnetic ring and an inductive coil wrapped around at least a portion of the ferromagnetic ring to generate a voltage from the magnetic flux in the ferromagnetic ring.

An apparatus including a first circuit and a second circuit. The first circuit may generate an output signal with a regulated voltage and maintain a constant switch frequency having a first on time and a first off time. The second circuit may generate a shifted signal based on a phase delay with respect to the output signal and maintain a shifted frequency having a second on time and a second off time. The second on time may follow the first on time by the phase delay. The second on time may be based on the first on time and transient conditions of a load. The apparatus may implement an automatic phase shift adjustment. A current sensing comparison may implement a cycle-by-cycle comparison between the output signal and the shifted signal to determine the second on time and perform a tuning operation to achieve inductor current balancing.