A power circuit is described that includes a transformer arranged to store energy. The power circuit further includes a parallel switch device arranged in parallel to a secondary side winding of the transformer, an output port coupled to a device and the secondary side winding of the transformer, and a control unit. The control unit is configured to receive, from the device, information indicative of a required voltage associated with the device, and control, based on the information, the parallel switch device to generate, based on an amount of energy stored at the transformer, the required voltage as an output voltage at the output port.

A switching converter, including an input interface for providing an input voltage, an output interface for providing at least one output voltage, a voltage conversion device for converting the provided input voltage into one of the at least one output voltage, and a clock generator for providing a working clock, the clock generator being configured in such a way that the clock generator provides a modulated basic clock as the working clock. A control unit including such a switching converter, and a method for operating such a switching converter, are also described.

Each phase of a multi-phase voltage converter includes a power stage, passive circuit, synchronous rectification (SR) switch, and control circuit. Each passive circuit couples its power stage to an output node of the voltage converter, and is switchably coupled to ground by the SR switch. The current through the SR switch has a half-cycle sinusoidal shape with a resonant frequency determined by the reactance of the passive circuit. The control circuit generates signals to control switches within the power stage and the SR switches. The control circuit measures current through the SR switch of each phase, and determines which of the phases has SR switch current which returns to zero the quickest. This phase is identified as a master, and the other phases of the voltage converter are aligned to this master phase such that none of the SR switches is turned off when negative current is flowing through it.

An inductor device may include a first electrically conductive path and a second electrically conductive path. The first electrically conductive path may extend from a first terminal of the inductor device to a second terminal of the inductor device. The second electrically conductive path may extend from a third terminal of the inductor device to a fourth terminal of the inductor device. The second electrically conductive path may be magnetically coupled to the first electrically conductive path. Each of the third terminal and the fourth terminal may be offset with respect to a virtual axis extending through the first terminal and the second terminal.

This disclosure describes systems, methods, and apparatus for driving a plurality of output circuits from a DC input signal using a resonant converter, the resonant converter comprising a switch network, a resonant tank, and a rectifier network, the resonant tank comprising: a resonant capacitor bridge coupled across the switch network; a plurality of branches, each branch comprising at least one series inductor coupled at a first end to the resonant capacitor bridge and at a second end to the rectifier network; and at least one parallel inductor; the rectifier network comprising one or more groups of transformers, each group coupled to one branch of the plurality of branches, and wherein the primary windings of the transformers of each group are coupled in parallel, and wherein the secondary windings are configured for coupling to an output load.

A control device of a multi-phase converter having N converter circuits connected in parallel includes: a determination unit configured to determine each share ratio of the N converter circuits to unevenly share input current to the multi-phase converter among the N converter circuits such that a conversion efficiency indicating a ratio of output power from the multi-phase converter with respect to input power to the multi-phase converter is higher in the case where the input current is unevenly shared by the N converter circuits compared to the case where the input current is evenly shared by the N converter circuits when the number of driven converter circuits is one or more and N−1 or less and the start condition is satisfied; and a diagnosis unit configured to diagnose an abnormality of the N converter circuits when the N converter circuits are driven in accordance with the determined share ratios.

A voltage converter includes a power stage, a passive circuit, a synchronous rectification (SR) switch component, and a control circuit. The passive circuit couples the power stage to an output node of the voltage converter, and is switchably coupled to ground by the SR switch component. The SR switch component includes a plurality of SR switches, which are independently controllable. The control circuit determines which of the SR switches are to be activated/enabled, and only uses those SR switches in its variable switching of the voltage converter. The determination of which SR switches are to be activated/enabled is based upon an estimate of the output current for the voltage converter. By using more SR switches when the voltage converter is fully loaded, and fewer SR switches when it is lightly loaded, the power loss of the SR switch component is minimized and the voltage converter is more power efficient.

Embodiments of a bidirectional low voltage power supply (LVPS) with a single pulse width modulator and method are generally described herein. In some embodiments, the bidirectional LVPS may include a first converter arranged to provide power from an input power source to a load and a second converter arranged to selectively recycle power from the load at an output of the first converter back to the input power source. Control circuitry may include switching circuitry that may be configured to select either the first power converter or the second power converter for reception of an output of a single PWM.

Current balancing for interleaved power converters. One example is a method of operating a power converter comprising: operating, at a switching frequency, a first power converter defining a first resonant primary, the first power converter provides a first portion of a total power provided to a load; operating, at the switching frequency, a second power converter defining a second resonant primary, the second power converter provides a second portion of the total power provided to the load; and limiting a resonant voltage of the first resonant primary by controlling energy in the first resonant primary, the controlling during periods of time when the first portion is larger than the second portion.

A rectifier arrangement includes at least one input alternating voltage terminal to which an alternating current can be supplied, at least two output direct voltage terminals at which direct current can be tapped and at least one series circuit with at least two sub-modules connected in series. Each sub-module of the series circuit includes at least one converter module, an inverter module and a transformer module. Each sub-module of the series circuit additionally includes a rectifier module. The outputs of the rectifier modules are connected in parallel and form the output direct voltage terminals of the rectifier arrangement.