Abstract: A multi-level inverter provides multi-level output voltage. The multi-level inverter includes at least one cascaded H-bridge multi-level module. Each H-bridge multi-level module comprises a first H-bridge multi-level leg and a second H-bridge multi-level leg connected in parallel. Each of the first and second H-bridge multi-level legs includes a first inverter leg and a second inverter leg coupled in parallel through a coupled inductor. The first and second inverter legs are coupled respectively to a primary winding and a second winding of the coupled inductor for providing first and second input voltages with multiple voltage levels. The primary and secondary windings of the coupled inductor are coupled in series and a junction node of the primary and secondary windings forms an output terminal of the H-bridge multi-level leg. The first input voltage has a predetermined phase shift relative to the second input voltage.

Abstract: The invention relates to a multi-level inverter and a method for providing multi-level output voltage by the multi-level inverter, wherein the multi-level inverter comprises at least one cascaded H bridge multi-level module, wherein each H bridge multi-level module comprises a first H bridge multi-level leg and a second H-bridge multi-level leg connected in parallel, wherein each of the first and second H bridge multi-level legs comprises a first inverter leg and a second inverter leg coupled in parallel through a coupled inductor, the first and second inverter legs are coupled respectively to a primary winding and a second winding of the coupled inductor for providing first and second input voltages with multiple voltage levels, the primary and secondary windings of the coupled inductor are coupled in series and a junction node of the primary and secondary windings forms an output terminal of the H bridge multi-level leg, wherein the first input voltage has a predetermined phase shift relative to the second

Abstract: The present invention relates to a power supply system (311) for supplying current to a gradient coil (303) of a magnetic resonance imaging system (100), the power supply system (311) comprising: an electrical power supply (309) to supply a first voltage to a gradient amplifier (307) for driving the gradient coil, the gradient amplifier output being connected to the gradient coil (303); an energy buffer having an input connected to the electrical power supply (309), the energy buffer being configured to supply second voltage to the gradient amplifier (307), the energy buffer being in parallel to the gradient amplifier (307) and the electrical power supply (309), the energy buffer comprising a voltage converter (313) configured to control the second voltage as to compensate for a variation in the first voltage resulting from the driving of the gradient coil (303).

Abstract: A power supply unit (130) powers at least one gradient coil (128) of a magnetic resonance (MR) examination system (110) with a main magnet (114) having, in at least one state of operation, a substantially static magnetic field strength, and with an MR measurement signal bandwidth. The power supply unit (130) includes a switched-mode power converter (134) for powering the at least one gradient coil (128), and including at least one switching member provided to switch between a conducting state configuration and an essentially non-conducting state configuration at a first fundamental switching frequency (fSW). A pulse control unit (132) is designed to provide switching pulses at the first fundamental switching frequency (fSW) for controlling the switching of the at least one switching member. Upon triggering by a trigger signal (142), the pulse control unit (132) is provided to change the first fundamental switching frequency (fSW) to at least a second fundamental switching frequency (fSW).

Abstract: A power supply unit (130) for powering at least one gradient coil (128) of a magnetic resonance (MR) examination system (110) with a main magnet (114) having, in at least one state of operation, a substantially static magnetic field strength, and with an MR measurement signal bandwidth, the power supply unit (130) comprising: a switched-mode power converter (134) for powering the at least one gradient coil (128), comprising at least one switching member provided to switch between a conducting state configuration and an essentially non-conducting state configuration at a first fundamental switching frequency (fSW); a pulse control unit (132) designed to provide switching pulses at the first fundamental switching frequency (fSW) for controlling the switching of the at least one switching member; wherein, upon triggering by a trigger signal (142), the pulse control unit (132) is provided to change the first fundamental switching frequency (fSW) to at least a second fundamental switching frequency (fSW).

Abstract: The present invention relates to a power supply system (311) for supplying current to a gradient coil (303) of a magnetic resonance imaging system (100), the power supply system (311) comprising: an electrical power supply (309) to supply a first voltage to a gradient amplifier (307) for driving the gradient coil, the gradient amplifier output being connected to the gradient coil (303); an energy buffer having an input connected to the electrical power supply (309), the energy buffer being configured to supply second voltage to the gradient amplifier (307), the energy buffer being in parallel to the gradient amplifier (307) and the electrical power supply (309), the energy buffer comprising a voltage converter (313) configured to control the second voltage as to compensate for a variation in the first voltage resulting from the driving of the gradient coil (303).