When a voltage application command is outputted to a three-phase winding of one system, a d-axis proportionality constant and a q-axis proportionality constant are set with Ld and Lq, respectively, as parameters; when voltage application commands are outputted to three-phase windings of two systems, a d-axis proportionality constant and a q-axis proportionality constant are set with [Ld+Md] and [Lq+Mq], respectively, as parameters.

An efficient solution to the problem of converting alternating signals into a plurality of signals having different signal characteristics in observation of different application requirements. This is achieved by a multiple input multiple output converter operated at a secondary side of an inductive power transfer system for converting at least one alternating input signal into a rectified alternating input signal and a further signal derived by averaging a switched voltage generated during rectification of the alternating input signal. The multiple input multiple output converter comprises at least one rectifier circuit adapted to rectify the alternating input signal and at least one averaging circuit adapted to average the switched voltage which is generated during rectification operation of the eat least one alternating input signal.

An apparatus may include a regulated power converter, a control engine configured to control the regulated power converter based upon a regulation control parameter, a period detection system and a parameter control system. The period detection system may be configured to monitor a signal to detect transient events at an output of the regulated power converter, wherein the transient events include a first transient event and a second transient event after the first transient event. The period detection system may be configured to determine, in response to the second transient event, a transient event period between the first transient event and the second transient event. The period detection system may be configured to determine transient event period information based upon the transient event period. The parameter control system may be configured to set the regulation control parameter to a value determined based upon the transient event period information.

An apparatus may include a regulated power converter, a control engine configured to control the regulated power converter based upon a regulation control parameter, a period detection system and a parameter control system. The period detection system may be configured to monitor a signal to detect transient events at an output of the regulated power converter, wherein the transient events include a first transient event and a second transient event after the first transient event. The period detection system may be configured to determine, in response to the second transient event, a transient event period between the first transient event and the second transient event. The period detection system may be configured to determine transient event period information based upon the transient event period. The parameter control system may be configured to set the regulation control parameter to a value determined based upon the transient event period information.

The present invention is directed at a battery powered turbine generator that can operate continuously, regardless of environmental conditions. This inexpensive system can operate regardless of night or day, in sunlight or wind, and does not require any fossil fuels.

The present invention is directed at a battery powered turbine generator that can operate continuously, regardless of environmental conditions. This inexpensive system can operate regardless of night or day, in sunlight or wind, and does not require any fossil fuels.

An electrical converter includes an inverter configured to provide at least one input AC voltage from an input DC voltage. The electrical converter further includes an AC-to-AC voltage converter configured to provide an output AC voltage from the at least one input AC voltage such that the output AC voltage has an amplitude that depends on a frequency of the at least one input AC voltage. A rectifier designed is configured to provide an output DC voltage from the output AC voltage.

An electrical converter includes an inverter configured to provide at least one input AC voltage from an input DC voltage. The electrical converter further includes an AC-to-AC voltage converter configured to provide an output AC voltage from the at least one input AC voltage such that the output AC voltage has an amplitude that depends on a frequency of the at least one input AC voltage. A rectifier designed is configured to provide an output DC voltage from the output AC voltage.

A power conversion system includes a first converter configured to convert an input voltage into discrete voltage levels, and provide each discrete voltage level at a corresponding output terminal. The power conversion system further includes a second converter configured to convert the voltages into modulated voltages. The power conversion system further includes a selection unit configured to alternatively output each of the modulated voltages across a pair of output terminals.

A power conversion system includes a first converter configured to convert an input voltage into discrete voltage levels, and provide each discrete voltage level at a corresponding output terminal. The power conversion system further includes a second converter configured to convert the voltages into modulated voltages. The power conversion system further includes a selection unit configured to alternatively output each of the modulated voltages across a pair of output terminals.