Abstract: In accordance with an embodiment, a method includes converting power by a power converter circuit having a plurality of converter cells coupled to a supply circuit. Converting the power includes a plurality of successive activation sequences and, in each activation sequence, activating at least some of the plurality of converter cells at an activation frequency. The activation frequency is dependent on at least one of an output power and an output current of the power converter circuit.

Abstract: A circuit arrangement includes a number of DC power sources. Each DC power source includes a rechargeable battery. The circuit arrangement also includes a number converter units. Each converter unit has input terminals and output terminals. The input terminals are coupled to one DC power source. The converter units form a series circuit between load terminals.

Abstract: A multiphase power converter circuit includes at least two single phase power converter circuits. Each single phase power converter circuit includes at least one converter series circuit with a number of converter units. The converter series circuit is configured to output a series circuit output current. A synchronization circuit is configured to generate at least one synchronization signal. At least one of the converter units is configured to generate an output current such that at least one of a frequency and a phase of the output current is dependent on the synchronization signal.

Abstract: In accordance with an embodiment, a method includes converting power by a power converter circuit having a plurality of converter cells coupled to a supply circuit. Converting the power includes a plurality of successive activation sequences and, in each activation sequence, activating at least some of the plurality of converter cells at an activation frequency. The activation frequency is dependent on at least one of an output power and an output current of the power converter circuit.

Abstract: A power converter and a method for operating a power converter are disclosed. In an embodiment the method for operating a power converter includes maintaining a first electronic switch switched off and an inductor demagnetized for a pause period before at least one of the plurality of drive cycles, pre-magnetizing the inductor connected in series with the first electronic switch, and discharging a parasitic capacitance of the first electronic switch using energy stored in the inductor by pre-magnetizing. The method further includes after discharging the parasitic capacitance, switching on for an on-period the first electronic switch.

Abstract: A circuit arrangement, includes output terminals that provide an output current and input terminals that receive a source current and a source voltage from a DC current source. A maximum power point tracker is coupled between the input terminals and the output terminals and a bypass circuit is coupled between the input terminals and the output terminals. The bypass circuit is configured to enter a bypass state dependent on the output current and dependent on the source current. The source current flows through the bypass circuit in the bypass state.

Abstract: A multiphase power converter circuit includes at least two single phase power converter circuits. Each single phase power converter circuit includes at least one converter series circuit with a number of converter units. The converter series circuit is configured to output a series circuit output current. A synchronization circuit is configured to generate at least one synchronization signal. At least one of the converter units is configured to generate an output current such that at least one of a frequency and a phase of the output current is dependent on the synchronization signal.

Abstract: A power converter circuit includes output terminals configured to receive an external voltage. A series circuit with a number of converter units is connected between the output terminals of the power converter circuit. Each converter unit includes input terminals configured to be coupled to a DC power source and output terminals configured to provide an output current. At least one converter unit of the converter units includes a signal generator configured to receive a synchronization signal and to generate a continuous synchronization signal from the synchronization signal. The power converter circuit can be operated in a normal operation mode. In the normal operation mode, the at least one converter unit is configured to regulate generation of the output current such that a frequency and/or a phase of the output current are dependent on the continuous synchronization signal.

Abstract: A power converter circuit includes a power converter with a plurality of series connected converter cells. Each of the plurality of converter cells includes at least one first half-bridge circuit including a first silicon MOSFET (Metal Oxide Semiconductor Field-Effect Transistor) and a second silicon MOSFET. At least one of the plurality of converter cells is configured to operate in a continuous current mode.

Abstract: Embodiments of the invention relate to a circuit for an active diode, a method for operating an active diode, and, based thereon, an integrated active diode system, a rectifier, and a system for voltage conversion and/or regulation, comprising at least one transistor by which a current defined as positive from a first connection to a second connection of the transistor can be controlled, and at least one measuring/control circuit (for determining the current by means of which the at least one transistor can be switched on for currents under and at most up to a predetermined, non-positive threshold value (i1<=ith<=0), and can otherwise be switched off.

Abstract: A resonant converter is described that includes at least one power switch. The at least one power switch is characterized by a non-linearity coefficient that is less than or equal to a first threshold and a figure-of-merit that is less than or equal to a second threshold. The figure-of-merit being associated with an on-resistance of the at least one power switch and an output charge of the at least one power switch.

Abstract: A semiconductor device arrangement includes a first semiconductor device having a load path and a plurality of second semiconductor devices, each having a load path between a first and a second load terminal and a control terminal. The second semiconductor devices have their load paths connected in series and connected in series to the load path of the first semiconductor device. Each of the second semiconductor devices has its control terminal connected to the load terminal of one of the other second semiconductor devices, and one of the second semiconductor devices has its control terminal connected to one of the load terminals of the first semiconductor device. Each of the second semiconductor devices has at least one device characteristic. At least one device characteristic of at least one of the second semiconductor devices is different from the corresponding device characteristic of others of the second semiconductor devices.

Abstract: In accordance with an embodiment, a method includes receiving by a drive circuit electrical power from a voltage tap of a first rectifier circuit that includes a load path and a voltage tap, and using the electrical power by the drive circuit to drive a second rectifier circuit that includes a load path. The load path of the first rectifier circuit and the load path of the second rectifier circuit are coupled to a common circuit node.

Abstract: Disclosed is a semiconductor device arrangement including a first semiconductor device having a load path, and a plurality of second transistors, each having a load path between a first and a second load terminal and a control terminal. The second transistors have their load paths connected in series and connected in series to the load path of the first transistor, each of the second transistors has its control terminal connected to the load terminal of one of the other second transistors, and one of the second transistors has its control terminal connected to one of the load terminals of the first semiconductor device.

Abstract: A power converter circuit includes a synchronization circuit that is configured to generate at least one synchronization signal. A series circuit includes a number of converter units configured to output an output current. At least one of the converter units includes a transformer and is configured to generate an output current such that a frequency or a phase of the generated output current is dependent on the synchronization signal.

Abstract: A super junction semiconductor device includes a super junction structure that is formed in a semiconductor body having a first and a second, parallel surface. The super junction structure includes first areas of the first conductivity type and second areas of a second conductivity type which is the opposite of the first conductivity type. In a cell area surrounded by an edge area, the super junction structure has a first nominal breakdown voltage in a first portion and a second nominal breakdown voltage, which differs from the first nominal breakdown voltage, in a second portion to provide improved avalanche ruggedness.

Abstract: A power circuit is described that includes a semiconductor body having a common substrate and a Gallium Nitride (GaN) based substrate. The GaN based substrate includes one or more GaN devices adjacent to a front side of the common substrate. The common substrate is electrically coupled to a node of the power circuit. The node of the power circuit is at a particular potential that is equal to, or more negative than, a potential at one or more load terminals of the one or more GaN devices.

Abstract: A rectifier circuit with a semiconductor element is disclosed. The semiconductor element includes at least one field effect transistor with a control electrode, and at least one driver. The driver cooperates with a voltage sensor, and controls the field effect transistor to a conducting state. The semiconductor element includes the voltage sensor insulated from the at least one field effect transistor. The voltage sensor includes a separate sensor electrode, and a sensor capacitance of the voltage sensor forms a non-linear voltage divider with a reference capacitance.

Abstract: A method for power control includes determining a load power of a load coupled to an output of an isolated AC/DC power supply. The method also includes, when the determined load power is less than a first threshold load power, providing the load power to the load from an interim power source.

Abstract: A voltage converter includes a first converter stage including a unipolar transistor coupled to a first inductive storage element, where the first converter stage is configured to provide a first output power signal including a first output current. Also, the voltage converter includes a second converter stage including a bipolar transistor coupled to a second inductive storage element, where the second converter stage is configured to provide a second output power including a second output current, and where a third output current is a sum of the first output current and the second output current. Additionally, the voltage converter includes a control circuit configured to control a power converter including the first output current and the second output current, where the first output current is higher than the second output current when the third output current has a first range of output current.