Abstract: In some examples, an apparatus includes a driver having a driver output, a capacitor having a first plate and a second plate, the first plate coupled to the driver output, and a transistor having a transistor gate, a transistor source, and a transistor drain. The apparatus also includes a first switch coupled between the second plate and the transistor gate, a second switch coupled between the second plate and the transistor drain, and a third switch coupled between the transistor gate and the transistor drain.

Abstract: The present invention relates to a semiconductor device, wherein the semiconductor substrate includes: a semiconductor layer; and a well region, the semiconductor device includes: a surface electrode provided on a second main surface on a side opposite to a first main surface; a back surface electrode provided on the first main surface; and an upper surface film covering an end edge portion of the surface electrode and at least part of an outer side region outside an end surface of the surface electrode of the semiconductor substrate, the well region includes a portion extending to the outer side region and a portion extending to an inner side region inside the end surface of the surface electrode, and the upper surface film includes at least one outer peripheral opening part provided along an outer periphery of the surface electrode away from the surface electrode of the outer side region.

Abstract: In some examples, a device includes a selector circuit configured to deliver power to a first driver circuit, where the first driver circuit is configured to activate and deactivate a first switch of a postregulator. The device also includes a startup regulator and a controller configured to cause the selector circuit to deliver power from the startup regulator to the first driver circuit. The controller is also configured to determine that a boost regulator is operational after delivering power from the startup regulator to the first driver circuit. The controller is further configured to cause the selector circuit to deliver power from the boost regulator to the first driver circuit in response to determining that the boost regulator is operational.

Abstract: A control circuit, system and method for switched-mode power supply are disclosed, the control circuit is for driving a first switch to convert an input voltage into an output voltage. The control circuit includes an on-time control unit, which receives a first signal characterizing switching frequency of first switch and a second signal characterizing current flowing through first switch and responsively generates a signal indicative of a turn-off instant for first switch. When a peak value of the current flowing through the first switch drops below a predefined value, the on-time control unit determines the turn-off instant for the first switch based on the first signal so that the switching frequency of the first switch is maintained at a target frequency. This design can effectively avoid the generation of audible noise, stabilize the output voltage against loading changes while maintaining desirable efficiency, and ensure operational safety of the switched-mode power supply.

Abstract: A power converter assembly includes a semi-conductor module, a heat sink mechanically connected to the semi-conductor module, a first busbar assembly on a first side of the heat sink, and a second busbar assembly on a second side of the heat sink opposite from the first side. The first and second busbar assemblies are electrically connected to one another. A power converter assembly includes a plurality of sets of semi-conductor modules, a common heat sink mechanically connected to each semi-conductor module, a first busbar assembly on a first side of the common heat sink, and a second busbar assembly on a second side of the common heat sink opposite from the first side. The first and second busbar assemblies are electrically connected to one another.

Abstract: A half-bridge module having two switching units, each of which includes multiple transistors connected in parallel and/or in series, in particular IGBTs or MOSFETs. The transistors are arranged on a first substrate. The half-bridge module has a temperature sensor matrix having a plurality of temperature sensors, and the temperature sensors are thermally connected to the transistors at least in some regions. A temperature sensor matrix is also provided.

Abstract: A method of operating an electrical system including an electrical power source configured to supply a first DC voltage at a first voltage level and a DC/DC converter coupled to the electrical power source and configured to supply a second DC voltage is provided. The method includes monitoring a level of current supplied by the DC/DC converter, determining, based on monitoring of the level of the current, that the DC/DC converter is saturated, and in response to determining that the DC/DC converter is saturated, regulating a level of voltage outputby the DC/DC converter. Related DC/DC converters and vehicle electrical systems are disclosed.

Abstract: In an embodiment a direct current to direct current (DC-DC) converter includes a first switching circuit configured to switch a supply of an input voltage to an energy storage circuit configured to generate an output voltage, a driving circuit configured to drive the first switching circuit according to a comparison between the output voltage and a comparison voltage and a soft-start circuit configured to raise the comparison voltage from a start voltage to a target voltage during a soft-start phase of the DC-DC converter having a soft-start duration, wherein the soft-start circuit comprises a soft-start capacitor configured to provide the comparison voltage during the start phase, the soft-start capacitor having a soft-start capacitance, an auxiliary capacitor having an auxiliary capacitance, a second switching circuit configured to alternately charge and discharge the auxiliary capacitor with an auxiliary current according to a clock signal having a clock frequency and a charging circuit.

Abstract: A method for particle abatement in a wafer processing tool implements at least one cleaning-purposed mobile electrostatic carrier (MESC) including electrostatic field generating (EFG) circuits. Each EFG circuit is charged with the cleaning-purposed MESC. The cleaning-purposed MESC is then loaded into the wafer processing tool in a facedown orientation. A normal-purposed MESC is loaded into the wafer processing tool in a faceup orientation. Next, foreign materials are bonded to the cleaning-purposed MESC as the cleaning-purposed MESC is moved along a processing path through the wafer processing tool in the facedown orientation. The normal-purposed MESC travels the processing path during normal operation of the wafer processing tool in the faceup orientation. The cleaning-purposed MESC is then unloaded from the wafer processing tool. Next, the foreign materials are debonded from the cleaning-purposed MESC by discharging each EFG circuit with the cleaning-purposed MESC.

Abstract: An electrical apparatus configured to electrically connect to a multi-phase alternating current (AC) electrical power distribution network includes: an input electrical network including: a plurality of input nodes, each configured to electrically connect to one phase of the multi-phase AC electrical power distribution network; at least one non-linear electronic component electrically connected to the input electrical network; an impedance network electrically connected between the input electrical network and ground; and a control system configured to: access a voltage signal that represents a voltage over time at the input electrical network; determine a frequency content of the voltage signal; determine a property of the frequency content; and determine whether an input current performance condition exists in the electrical apparatus based the property of the frequency content.

Abstract: The invention relates to electrical equipment comprising: a heatsink comprising an internal volume delimited by at least two opposite faces, a busbar, said busbar coming against said two opposite faces of the heatsink in such a way as to be cooled by said heatsink.

Abstract: Subject matter disclosed herein may relate to power converters, and may more particularly relate to multi-stage hybrid power converters, for example.

Abstract: Provided is a determination method of differential protection suitable for an electricity transmission line with multi-terminal T-connection.

Abstract: A passive, current dependent inductivity (1) comprises a magnetic core (2), windings (3) and at least one bank air gap (4). A saturation region (5) made of magnetic material is arranged between the bank air gap (4) and the windings (3). A magnetic flux path (6) bifurcates into a first path (61) passing through the saturation region (5) and into a second path (62) passing through the bank air gap (4) and bypassing the saturation region (5). The magnetic resistance of the first path (61) is lower than the magnetic resistance of the second path (62) for winding currents below a first saturation current (7a) and whereby the magnetic resistance of the second path (62) is lower than the magnetic resistance of the first path (61) for winding currents above the first saturation current (7a) due to saturation of the saturation region.

Abstract: A control circuit for a switching converter having a main power switch, the control circuit including: a voltage generation circuit configured to be connected with a common connection terminal of the main power switch and an inductor to receive a drain-source voltage of the main power switch, and to generate a first voltage according to the drain-source voltage; a valley detection circuit configured to generate a valley detection signal according to the first voltage when the drain-source voltage resonates to a valley; and where the control circuit is configured to turn on the main power switch according to the valley detection signal.

Abstract: This disclosure is directed to power systems for transferring power between electrical components. An exemplary power system includes a first electrical component (e.g., an inverter system) having a current sensor assembly for detecting current flowing between the first electrical component and a second electrical component (e.g., an electric motor) in order to more reliably manage and control operation of the second electrical component. The current sensor assembly may include an integrated cooler that includes an internal cooling circuit configured to circulate coolant for cooling one or more bus bars of the current sensor assembly.

Abstract: An apparatus includes a soft start manager such as implemented via hardware, software, or a combination of hardware and software. The soft start manager receives input parameter from a power supply; the input parameter (such as output voltage, duty cycle, input voltage, etc.) is associated with conversion of the input voltage into an output voltage that powers a load. The soft start manager monitors a magnitude of the input parameter. Based at least in part on the magnitude of the input parameter, the soft start manager controls a switching period applied to switch circuitry in the power supply.

Abstract: The invention discloses a power module and a power conversion device. The power module includes a primary converting unit including a first active device unit; a secondary converting unit including a second active device unit; a transformer including a primary unit connected to the primary converting unit and a secondary unit connected to the secondary converting unit; a first heat dissipating unit on which the primary unit and the first active device unit are disposed; a second heat dissipating unit on which the secondary unit and the second active device unit are disposed; and an insulating plate including an insulating plate body and a semi-conducting layer disposed on a surface of the insulating plate body.

Abstract: A measurement device configured to deliver a voltage corresponding to an overlay of an input voltage applied to the terminals of the measurement device and of an image voltage of a current circulating in a first capacitor to the terminals of which the input voltage is applied, the measurement device includes a shunt filter intended to be mounted in parallel with the first capacitor and comprising a second capacitor and a first resistor mounted in series with the second capacitor, a second resistor mounted in parallel with the second capacitor.

Abstract: A control system for a multi-phase power system includes a first phase line, a second phase line, and a third phase line. The control system includes a plurality of regulator controls including a first regulator control configured to control a first tap changer associated with the first phase line, a second regulator control configured to control a second tap changer associated with the second phase line, a third regulator control configured to control a third tap changer associated with the third phase line, and an electronic processor coupled to the first regulator control, the second regulator control, and the third regulator control. The electronic processor is configured to regulate the voltage of the multi-phase system using the first, second, and third regulator controls.