Abstract: A circuit including a source, a load, and an isolation circuit for controllably isolating the load from the source. The isolation circuit is disposed between the source and the load. The isolation circuit includes at least one insulated-gate bipolar transistor (IGBT) and at least one gate turn-off thyristor (GTO) in parallel with the insulated-gate bipolar transistor. When no fault condition exists, the GTO is configured to be ON to couple the load to the source. When a fault condition exists, the at least one IGBT is configured to turn ON. After the at least one IGBT turns ON, the at least one GTO is configured to turn OFF. After a predetermined amount of time, reflecting the post fabrication alteration to the GTO's minority carrier lifetime (e.g. electron irradiation), after the at least one GTO turns OFF, the at least one IGBT is configured to turn OFF.

Abstract: A circuit including a source, a load, and an isolation circuit for controllably isolating the load from the source. The isolation circuit is disposed between the source and the load. The isolation circuit includes at least one insulated-gate bipolar transistor (IGBT) and at least one gate turn-off thyristor (GTO) in parallel with the insulated-gate bipolar transistor. When no fault condition exists, the GTO is configured to be on to couple the load to the source. When a fault condition exists, the at least one IGBT is configured to turn on. After the at least one IGBT turns on, the at least one GTO is configured to turn off. After a predetermined amount of time after the at least one GTO turns off, the at least one IGBT is configured to turn off.

Abstract: A semiconductor switching device for switching high voltage and high current. The semiconductor switching device includes a control-triggered stage and one or more auto-triggered stages. The control-triggered stage includes a plurality of semiconductor switches, a breakover switch, a control switch, a turn-off circuit, and a capacitor. The control-triggered stage is connected in series to the one or more auto-triggered stages. Each auto-triggered stage includes a plurality of semiconductor switches connected in parallel, a breakover switch, and a capacitor. The control switch provides for selective turn-on of the control-triggered stage. When the control-triggered stage turns on, the capacitor of the control-triggered stage discharges into the gates of the plurality of semiconductor switches of the next highest stage to turn it on. Each auto-triggered stage turns on in a cascade fashion as the capacitor of the adjacent lower stage discharges or as the breakover switches of the auto-triggered stages turn on.

Abstract: A circuit for turning OFF a thyristor. The circuit includes at least one first circuit element configured to provide a high reverse turn-OFF voltage to the thyristor gate for a predetermined period of time. Immediately following the predetermined period of time, at least one second circuit element provides a normal reverse turn-OFF voltage to the thyristor gate. The normal reverse turn-OFF voltage is substantially lower than the high reverse turn-OFF voltage.

Abstract: A semiconductor switching device for switching high voltage and high current. The semiconductor switching device includes a control-triggered stage and one or more auto-triggered stages. The control-triggered stage includes a plurality of semiconductor switches, a breakover switch, a control switch, a turn-off circuit, and a capacitor. The control-triggered stage is connected in series to the one or more auto-triggered stages. Each auto-triggered stage includes a plurality of semiconductor switches connected in parallel, a breakover switch, and a capacitor. The control switch provides for selective turn-on of the control-triggered stage. When the control-triggered stage turns on, the capacitor of the control-triggered stage discharges into the gates of the plurality of semiconductor switches of the next highest stage to turn it on. Each auto-triggered stage turns on in a cascade fashion as the capacitor of the adjacent lower stage discharges or as the breakover switches of the auto-triggered stages turn on.

Abstract: A semiconductor switching device for switching high voltage and high current. The semiconductor switching device includes a control-triggered stage and one or more auto-triggered stages. The control-triggered stage includes a plurality of semiconductor switches, a breakover switch, a control switch, a turn-off circuit, and a capacitor. The control-triggered stage is connected in series to the one or more auto-triggered stages. Each auto-triggered stage includes a plurality of semiconductor switches connected in parallel, a breakover switch, and a capacitor. The control switch provides for selective turn-on of the control-triggered stage. When the control-triggered stage turns on, the capacitor of the control-triggered stage discharges into the gates of the plurality of semiconductor switches of the next highest stage to turn it on. Each auto-triggered stage turns on in a cascade fashion as the capacitor of the adjacent lower stage discharges or as the breakover switches of the auto-triggered stages turn on.

Abstract: A semiconductor switching device for switching high voltage and high current. The semiconductor switching device includes a control-triggered stage and one or more auto-triggered stages. The control-triggered stage includes a plurality of semiconductor switches, a breakover switch, a control switch, a turn-off circuit, and a capacitor. The control-triggered stage is connected in series to the one or more auto-triggered stages. Each auto-triggered stage includes a plurality of semiconductor switches connected in parallel, a breakover switch, and a capacitor. The control switch provides for selective turn-on of the control-triggered stage. When the control-triggered stage turns on, the capacitor of the control-triggered stage discharges into the gates of the plurality of semiconductor switches of the next highest stage to turn it on. Each auto-triggered stage turns on in a cascade fashion as the capacitor of the adjacent lower stage discharges or as the breakover switches of the auto-triggered stages turn on.

Abstract: A gate turn-off thyristor (GTO) device has a lower portion, an upper portion and a lid. The lower portion has a lower base region of a first conductivity type, and a lower emitter region of a second conductivity type disposed at or from a lower surface of the lower base region. A lower junction is formed between the lower base region and the lower emitter region. The upper portion has an upper base region of the second conductivity type, and upper emitter regions of the first conductivity type disposed at or from an upper surface of the upper base region. An upper-lower junction is formed between the lower base region and the upper base region, and upper junctions are formed between the upper base region and the upper emitter regions. The upper base region and upper emitter regions form an upper base surface with first conductive contacts to the upper base region alternating with second conductive contacts to the upper emitter regions. The lid has a layer of insulator with upper and lower surfaces.

Abstract: A voltage regulator apparatus comprises a transformer having a primary winding and a secondary winding, a plurality of further windings selectively connected to one of the primary winding and secondary winding, and a plurality of solid state selectors respectively coupled to each of the plurality of further windings to one of i) connect the further winding in series with the primary winding or the secondary winding and ii) bypass the further winding.

Abstract: This high-power semiconductor device comprises (a) a disk of refractory metal having flat faces at its opposite sides and (b) two wafers of a semiconductor material having a coefficient of expansion similar to that of the refractory metal, the wafers being alloyed to the faces of the refractory metal disk in substantially aligned relationship to each other to form an assembly of the wafer and the disk with alloyed joints between the wafers and the disk.

Abstract: The power thyristor of this invention has a cellular emitter structure. Each cell also has a FET assisted turn-on gate integrated into the cell. A turn-on gate voltage of one polarity is applied to a FET gate element that overlies the surface of the cell and to the turn-on gate integrated into the cell. When this voltage is so applied, a channel underlying the FET gate element becomes conductive, which allows the integrated turn-on gate to provide drive to the upper base-upper emitter junction of the thyristor cell thereby turning the thyristor cell on.

Abstract: This thyristor comprises a main current-carrying portion in the form of a semiconductor body having four layers, with contiguous layers being of different P and N conductivity types and with three back-to-back PN junctions between contiguous layers. One end layer constitutes an anode layer, an opposite end layer constitutes a cathode layer, and an intermediate layer contiguous with the cathode layer constitutes a gate layer. The cathode layer is divided into many elongated fingers, thereby dividing the PN junction between the cathode layer and the gate layer into many discrete PN subjunctions between the fingers and the gate layer. These subjunctions are effectively in parallel with each other so as to share the main current through the thyristor when the thyristor is "on". The gate layer has predetermined surface regions adjacent the cathode layer that are uncovered by the cathode-layer fingers and that respectively surround the PN subjunctions between the fingers and the gate layer.

Abstract: An AC solid state relay in a single inline package (SIP) comprised of dual silicon controlled rectifiers (SCRs) with a supporting circuitry mounted directly on an alumina substrate with molecularly bonded copper metalization layers and heat spreader all coated in a thermally conductive epoxy. And a DC solid state relay in a single inline package (SIP) comprised of an NPN power transistor with a supporting circuitry mounted directly on an alumina substrate with molecularly bonded copper metalization layers and heat spreader all coated in a thermally conductive epoxy.

Abstract: An AC solid state relay in a single inline package (SIP) comprised of dual silicon controlled rectifiers (SCRs) with a supporting circuitry mounted directly on an alumina substrate with molecularly bonded copper metalization layers and heat spreader all coated in a thermally conductive epoxy. And a DC solid state relay in a single inline package (SIP) comprised of an NPN power transistor with a supporting circuitry mounted directly on an alumina substrate with molecularly bonded copper metalization layers and heat spreader all coated in a thermally conductive epoxy.

Abstract: This thyristor comprises a main current-carrying portion in the form of a semiconductor body having four layers, with contiguous layers being of different P and N conductivity types and with three back-to-back PN junctions between contiguous layers. One end layer constitutes an anode layer, an opposite end layer constitutes a cathode layer, and an intermediate layer contiguous with the cathode layer constitutes a gate layer. The cathode layer is divided into many elongated fingers, thereby dividing the PN junction between the cathode layer and the gate layer into many discrete PN subjunctions between the fingers and the gate layer. These subjunctions are effectively in parallel with each other so as to share the main current through the thyristor when the thyristor is "on". The gate layer has predetermined surface regions adjacent the cathode layer that are uncovered by the cathode-layer fingers and that respectively surround the PN subjunctions between the fingers and the gate layer.