Abstract: The semiconductor device includes a plurality of first flat plates containing a material that absorbs an electromagnetic wave at a high frequency. Any of the first flat plates is disposed above the first connecting wire, and any other of the first flat plates is disposed above the second connecting wire.

Abstract: A semiconductor device provides a gate electrode formed on a lateral face of a wide trench, and thereby the gate electrode is covered by a gate insulating layer and a thick insulating layer to be an inter layer. Therefore, a parasitic capacitance of the gate becomes small, and there is no potential variation of the gate since there is no floating p-layer so that a controllability of the dv/dt can be improved. In addition, the conductive layer between the gate electrodes can relax the electric field applied to the corner of the gate electrode. In consequence, compatibility of low loss and low noise and high reliability can be achieved.

Abstract: Disclosed herein is a power semiconductor module including: a circuit board having gate, emitter, and collector patterns formed thereon; a first semiconductor chip mounted on the circuit board, having gate and emitter terminals each formed on one surface thereof, and having a collector terminal formed on the other surface thereof; a second semiconductor chip mounted on the first semiconductor chip, having a cathode terminal formed on one surface thereof, and having an anode terminal formed on the other surface thereof; a first conductive connection member having one end disposed between the collector terminal of the first semiconductor chip and the cathode terminal of the second semiconductor chip and the other end contacting the collector pattern of the circuit board; and a second conductive connection member having one end contacting the anode terminal of the second semiconductor chip and the other end contacting the emitter pattern of the circuit board.

Abstract: Junction-isolated blocking voltage devices and methods of forming the same are provided. In certain implementations, a blocking voltage device includes an anode terminal electrically connected to a first p-well, a cathode terminal electrically connected to a first n-well, a ground terminal electrically connected to a second p-well, and an n-type isolation layer for isolating the first p-well from a p-type substrate. The first p-well and the first n-well operate as a blocking diode. The blocking voltage device further includes a PNPN silicon controlled rectifier (SCR) associated with a P+ region formed in the first n-well, the first n-well, the first p-well, and an N+ region formed in the first p-well. Additionally, the blocking voltage device further includes an NPNPN bidirectional SCR associated with an N+ region formed in the first p-well, the first p-well, the n-type isolation layer, the second p-well, and an N+ region formed in the second p-well.

Abstract: Some aspects relate to a semiconductor device disposed on a semiconductor substrate. The device includes an STI region that laterally surrounds a base portion of a semiconductor fin. An anode region, which has a first conductivity type, and a cathode region, which has a second conductivity type, are arranged in an upper portion of the semiconductor fin. A first doped base region, which has the second conductivity type, is arranged in the base of the fin underneath the anode region. A second doped base region, which has the first conductivity type, is arranged in the base of the fin underneath the cathode region. A current control unit is arranged between the anode region and the cathode region. The current control unit is arranged to selectively enable and disable current flow in the upper portion of the fin based on a trigger signal. Other devices and methods are also disclosed.

Abstract: An electrostatic discharge (ESD) protection circuit is coupled between first and second pads to protect an internal circuit therebetween. Under a normal operating condition, a voltage on the first pad is higher than that on the second pad. The ESD protection circuit includes a substrate of a first conductivity type; first well of a second conductivity type in the substrate, wherein the first well is coupled to the first pad; a snapback device housed in the first well; and a diode string in the substrate, connected in series with the snapback device and separated from the first well, wherein the serially connected diode string and snapback device is connected between the first pad and the second pad. With the isolation from the first well, the holding voltage of the ESD protection circuit can be tuned by adjusting the number of diodes in the diode string without using a guard ring.

Abstract: To provide a semiconductor device in which a rectifying element capable of reducing a leak current in reverse bias when a high voltage is applied and reducing a forward voltage drop Vf and a transistor element are integrally formed on a single substrate. A semiconductor device has a transistor element and a rectifying element on a single substrate. The transistor element has an active layer formed on the substrate and three electrodes (source electrode, drain electrode, and gate electrode) disposed on the active layer. The rectifying element has an anode electrode disposed on the active layer, a cathode electrode which is the drain electrode, and a first auxiliary electrode between the anode electrode and cathode electrode.

Abstract: A semiconductor device includes: an n?-type base layer; a p-type base layer formed in a part of a front surface portion of the n?-type base layer; an n+-type source layer formed in a part of a front surface portion of the p-type base layer; a gate insulating film formed on the front surface of the p-type base layer between the n+-type source layer and the n?-type base layer; a gate electrode that faces the p-type base layer through the gate insulating film; a p-type column layer formed continuously from the p-type base layer in the n?-type base layer; a p+-type collector layer formed in a part of a rear surface portion of the n?-type base layer; a source electrode electrically connected to the n+-type source layer; and a drain electrode electrically connected to the n?-type base layer and to the p+-type collector layer.

Abstract: A semiconductor device includes a superjunction structure. The influence of external charge on device performance is suppressed using a shield electrode, field plate electrodes, and cover electrodes in various configurations. Optional embodiments include placing an interconnection film between certain electrodes and the upper surface of the superjunction structure. Cover electrodes may also be connected to various potentials to limit the effects of external charge on device performance.

Abstract: A semiconductor device includes a parasitic silicon-controlled rectifier (SCR) and a first transistor. The parasitic SCR includes a parasitic pnp bipolar junction transistor (BJT) and a parasitic npn BJT. The first transistor is coupled between a first power supply node and an emitter of the parasitic pnp BJT. The first transistor includes a first terminal coupled to the first power supply node, a second terminal coupled to the emitter of the parasitic pnp BJT, and a control terminal. The first transistor is not positioned between a base of the pnp BJT and the first power supply node. The first transistor limits current conducted by the parasitic pnp BJT following a single-event latch-up (SEL) event.

Abstract: A semiconductor device includes a first well region of a first conductivity type, a second well region of a second conductive type within the first well region. A first region of the first conductivity type and a second region of the second conductivity type are disposed within the second well region. A third region of the first conductivity type and a fourth region of the second conductivity type are disposed within the first well region, wherein the third region and the fourth region are separated by the second well region. The semiconductor device also includes a switch device coupled to the third region.

Abstract: A device includes a semiconductor substrate, and an insulation region extending from a top surface of the semiconductor substrate into the semiconductor substrate. The device further includes a first node and a second node, and an Electro-Static Discharge (ESD) device coupled between the first node and the second node. The ESD device includes a semiconductor fin adjacent to and over a top surface of the insulation region. The ESD device is configured to, in response to an ESD transient on the first node, conduct a current from the first node to the second node.

Abstract: A vertical electro-optical component and a method for forming the same are provided. The vertical electro-optical component includes a substrate, a first electrode layer formed on the substrate, a patterned insulating layer formed on the first electrode layer, a metal layer formed on the patterned insulating layer, a semiconductor layer formed on the first electrode layer, and a second electrode layer formed on the semiconductor layer, wherein the semiconductor layer encapsulates the patterned insulating layer and the metal layer. The vertical electro-optical component thus has a low operational voltage of a vertical transistor and a high reaction speed of a photo diode, and may be used to form light-emitting transistors.

Abstract: A semiconductor controlled rectifier (FIG. 4A) for an integrated circuit is disclosed. The semiconductor controlled rectifier comprises a first lightly doped region (100) having a first conductivity type (N) and a first heavily doped region (108) having a second conductivity type (P) formed within the first lightly doped region. A second lightly doped region (104) having the second conductivity type is formed proximate the first lightly doped region. A second heavily doped region (114) having the first conductivity type is formed within the second lightly doped region. A buried layer (101) having the first conductivity type is formed below the second lightly doped region and electrically connected to the first lightly doped region. A third lightly doped region (102) having the second conductivity type is formed between the second lightly doped region and the third heavily doped region.

Abstract: A semiconductor device includes a base layer, a second conductivity type semiconductor layer, a first insulating film, and a first electrode. The first insulating film is provided on an inner wall of a plurality of first trenches extending from a surface of the second conductivity type semiconductor layer toward the base layer side, but not reaching the base layer. The first electrode is provided in the first trench via the first insulating film, and provided in contact with a surface of the second conductivity type semiconductor layer. The second conductivity type semiconductor layer includes first and second regions. The first region is provided between the first trenches. The second region is provided between the first second conductivity type region and the base layer, and between a bottom part of the first trench and the base layer. The second region has less second conductivity type impurities than the first region.

Abstract: A semiconductor device including: an FET; a MOSFET having a drain thereof connected with a source of the FET; a resistor having one end thereof connected with a gate of the FET and having the other end thereof connected with a source of the MOSFET; and a diode having an anode thereof connected with the gate of the FET and having a cathode thereof connected with the source of the MOSFET.

Abstract: A semiconductor device includes a semiconductor substrate that includes a plurality of section having different thicknesses. The sections include a first section having a first thickness and a second section having a second thickness, the second section is the thinnest section among all the sections, and the first thickness is greater than the second thickness. A plurality of isolation trenches penetrates the semiconductor substrate for defining a plurality of element-forming regions in the first section and the second section. A plurality of elements is located at respective ones of the plurality of element-forming regions. The elements include a double-sided electrode element that includes a pair of electrodes separately disposed on the first surface and the second surface, and the double-sided electrode element is located in the second section.

Abstract: A power module includes a semiconductor device having at least one electrode surface on each side thereof, a first conductive member connected to the electrode surface provided on one side of the semiconductor device with solder, and a second conductive member connected to the electrode surface provided on the other side of the semiconductor device with solder, with at least one of the electrode surfaces provided on the one side of the semiconductor device being double comb-shaped.

Abstract: A bidirectional electrostatic discharge (ESD) protection device includes a substrate having a topside semiconductor surface that includes a first silicon controlled rectifier (SCR) and a second SCR formed therein including a patterned p-buried layer (PBL) including a plurality of PBL regions. The first SCR includes a first and second n-channel remote drain MOS device each having a gate, a source within a p-body, and sharing a first merged drain. The second SCR includes a third and a fourth n-channel remote drain MOS device each having a gate, a source within a p-body, and sharing a second merged drain. The plurality of PBL regions are directly under at least a portion of the sources while being excluded from being directly under either of the merged drains.

Abstract: A semiconductor device comprises a vertical MOS transistor including a semiconductor substrate having a silicon pillar, a gate electrode formed along a sidewall of the silicon pillar, a gate insulating film formed between the gate electrode and the silicon pillar, an upper diffusion layer formed on the top of the silicon pillar, and a lower diffusion layer formed lower than the upper diffusion layer in the semiconductor substrate; and a pad electrically connected to the lower diffusion layer. Breakdown occurs between the lower diffusion layer and the semiconductor substrate when a surge voltage is applied.

Abstract: A stabilizing plate portion is formed in a region of a first main surface lying between first and second insulated gate field effect transistor portions. The stabilizing plate portion includes a first stabilizing plate arranged closest to the first insulated gate field effect transistor portion and a second stabilizing plate arranged closest to the second insulated gate field effect transistor portion. An emitter electrode is electrically connected to an emitter region of each of the first and second insulated gate field effect transistor portions, electrically connected to each of the first and second stabilizing plates, and arranged on the entire first main surface lying between the first and second stabilizing plates, with an insulating layer being interposed.

Abstract: Some aspects relate to a semiconductor device disposed on a semiconductor substrate. The device includes an STI region that laterally surrounds a base portion of a semiconductor fin. An anode region, which has a first conductivity type, and a cathode region, which has a second conductivity type, are arranged in an upper portion of the semiconductor fin. A first doped base region, which has the second conductivity type, is arranged in the base of the fin underneath the anode region. A second doped base region, which has the first conductivity type, is arranged in the base of the fin underneath the cathode region. A current control unit is arranged between the anode region and the cathode region. The current control unit is arranged to selectively enable and disable current flow in the upper portion of the fin based on a trigger signal. Other devices and methods are also disclosed.

Abstract: Disclosed herein is a power semiconductor device including: a base substrate having one surface and the other surface and formed of a first conductive type drift layer; a first conductive type diffusion layer formed on one surface of the base substrate and having a concentration higher than that of the first conductive type drift layer; and a trench formed so as to penetrate through the second conductive type well layer and the first conductive type diffusion layer from one surface of the base substrate including the second conductive type well layer in a thickness direction.

Abstract: Provided is a transistor device including at least a vertical transistor structure. The vertical transistor structure includes a substrate, a dielectric layer, a gate, a first doped region, a second doped region, a third doped region, and a fourth doped region. The dielectric layer is disposed in a trench of the substrate. The gate is disposed in the dielectric layer. The gate defines, at both sides thereof, a first channel region and a second channel region in the substrate. The first doped region and the third doped region are disposed in the substrate and located below the first channel region and the second channel region, respectively. The second doped region and the fourth doped region are disposed in the substrate and located above the first channel region and the second channel region, respectively.

Abstract: A semiconductor device including a semiconductor substrate in which a diode region and an IGBT region are formed is provided. The diode region includes a first layer embedded in a diode trench reaching a diode drift layer from an upper surface side of the semiconductor substrate, and a second layer which is buried in the first layer and which has a lower end located deeper than a boundary between a diode body layer and the diode drift layer. The second layer pressures the first layer in a direction from inside to outside of the diode trench. A lifetime control region is formed in the diode drift layer at least at the depth of the lower end of the second layer, and a crystal defect density inside the lifetime control region is higher than a crystal defect density outside the lifetime control region.

Abstract: The present invention relates to a technique of semiconductor devices, and provides a semiconductor device, which uses two controllable current sources to control the electron current and the hole current of the voltage-sustaining region of a thyristor under conduction state, making the sum of current between anode and cathode close to saturation under high voltage, thus avoiding the current crowding effect in local region and increasing the reliability of the device. Besides, it further provides a method of implementing the two current sources in the device and a method to improve the switching speed.

Abstract: A power semiconductor device includes a first semiconductor layer of a first conductivity type, a first drift layer, and a second drift layer. The first drift layer includes a first epitaxial layer of the first conductivity type, a plurality of first first-conductivity-type pillar layers, and a plurality of first second-conductivity-type pillar layers. The second drift layer is formed on the first drift layer and includes a second epitaxial layer of the first conductivity type, a plurality of second second-conductivity-type pillar layers, a plurality of second first-conductivity-type pillar layers, a plurality of third second-conductivity-type pillar layers, and a plurality of third first-conductivity-type pillar layers. The plurality of second second-conductivity-type pillar layers are connected to the first second-conductivity-type pillar layers. The plurality of second first-conductivity-type pillar layers are connected to the first first-conductivity-type pillar layers.

Abstract: A technique for addressing single-event latch-up (SEL) in a semiconductor device includes determining a location of a parasitic silicon-controlled rectifier (SCR) in an integrated circuit design of the semiconductor device. In this case, the parasitic SCR includes a parasitic pnp bipolar junction transistor (BJT) and a parasitic npn BJT. The technique also includes incorporating a first transistor between a first power supply node and an emitter of the parasitic pnp BJT in the integrated circuit design. The first transistor includes a first terminal coupled to the first power supply node, a second terminal coupled to the emitter of the parasitic pnp BJT, and a control terminal. The first transistor is not positioned between a base of the pnp BJT and the first power supply node. The first transistor limits current conducted by the parasitic pnp bipolar junction transistor following an SEL.

Abstract: A monolithic bidirectional switching device includes a drift layer having a first conductivity type and having an upper surface, and first and second vertical metal-oxide semiconductor (MOS) structures at the upper surface of the drift layer. The drift layer provides a common drain for the first and second vertical MOS structures. The first and second vertical MOS structures are protected by respective first and second edge termination structures at the upper surface of the drift layer. A monolithic bidirectional switching device according to further embodiments includes a vertical MOS structure at the upper surface of the drift layer, and a diode at the upper surface of the drift layer. The drift layer provides a drain for the vertical MOS structure and a cathode for the diode, and the vertical MOS structure and the diode are protected by respective first and second edge termination structures.

Abstract: A MOS transistor protected against overvoltages formed in an SOI-type semiconductor layer arranged on an insulating layer itself arranged on a semiconductor substrate including a lateral field-effect control thyristor formed in the substrate at least partly under the MOS transistor, a field-effect turn-on region of the thyristor extending under at least a portion of a main electrode of the MOS transistor and being separated there-from by said insulating layer, the anode and the cathode of the thyristor being respectively connected to the drain and to the source of the MOS transistor, whereby the thyristor turns on in case of a positive overvoltage between the drain and the source of the MOS transistor.

Abstract: A rectifier circuit has a rectifier element and a unipolar field-effect transistor connected in series between a first terminal and a second terminal. The rectifier element comprises a first electrode and a second electrode disposed in a direction of a forward current flowing from the first terminal to the second terminal. The field-effect transistor has a gate electrode having a potential identical to a potential at the first electrode, and a source electrode and a drain electrode connected in series to the rectifier element and passing a current depending on the potential at the gate electrode. A breakdown voltage between the gate electrode and drain electrode of the field-effect transistor in a reverse bias mode, where a potential at the second terminal is higher than a potential at the first terminal, being set higher than a breakdown voltage of the rectifier element.

Abstract: A monolithic compound semiconductor structure is disclosed. The monolithic compound semiconductor structure comprises a substrate, an n-type FET epitaxial structure, an n-type etching-stop layer, a p-type insertion layer, and an npn HBT epitaxial structure, and it can be used to form an FET, an HBT, or a thyristor.

Abstract: A bidirectional switch includes a semiconductor element and a substrate potential stabilizer. The semiconductor element includes a first ohmic electrode and a second ohmic electrode, and a first gate electrode and a second gate electrode, which are sequentially formed on the first ohmic electrode between the first ohmic electrode and the second ohmic electrode. The substrate potential stabilizer sets a potential of the substrate lower than higher one of a potential of the first ohmic electrode or a potential of the second ohmic electrode.

Abstract: An integrated circuit includes a bidirectional ESD device which has a plurality of parallel switch legs. Each switch leg includes a first current switch and a second current switch in a back-to-back configuration. A first current supply node of each first current switch is coupled to a first terminal of the ESD device. A second current supply node of each second current switch is coupled to a second terminal of the ESD device. A first current collection node of each first current switch is coupled to a second current collection node of the corresponding second current switch. The first current collection nodes in each first current switch is not coupled to any other first current collection node, and similarly, the second current collection node in each instance second current switch is not coupled to any other second current collection node.

Abstract: A semiconductor element and an operating method thereof are provided. The semiconductor element comprises a first metal oxide semiconductor (MOS) and a second MOS. The second MOS is electrically connected to the first MOS. The second MOS includes a floating bipolar junction transistor (BJT).

Abstract: A modified MOSFET structure comprises an integrated field effect rectifier connected between the source and drain of the MOSFET to shunt current during switching of the MOSFET. The integrated FER provides faster switching of the MOSFET due to the absence of injected carriers during switching while also decreasing the level of EMI relative to discrete solutions. The integrated structure of the MOSFET and FER can be fabricated using N-, multi-epitaxial and supertrench technologies, including 0.25 ?m technology. Self-aligned processing can be used.

Abstract: An organic light emitting element includes an organic light emitting diode formed on a substrate, coupled to a transistor including a gate, a source and a drain and including a first electrode, an organic thin film layer and a second electrode; a photo diode formed on the substrate and having a semiconductor layer including a high-concentration P doping region, a low-concentration P doping region, an intrinsic region and a high-concentration N doping region; and a controller that controls luminance of light emitted from the organic light emitting diode, to a constant level by controlling a voltage applied to the first electrode and the second electrode according to the voltage outputted from the photo diode.

Abstract: The invention discloses an ESD protection circuit, comprising a P-type substrate; an N-well formed on the P-type substrate; a P-doped region formed on the N-well, wherein the P-doped region is electrically connected to an input/output terminal of a circuit under protection; a first N-doped region formed on the P-type substrate, the first N-doped region is electrically connected to a first node, and the P-doped region, the N-well, the P-type substrate, and the first N-doped region constitute a silicon controlled rectifier; and a second N-doped region formed on the N-well and electrically connected to a second node, wherein a part of the P-doped region and the second N-doped region constitute a discharging path, and when an ESD event occurs at the input/output terminal, the silicon controlled rectifier and the discharging path bypass electrostatic charges to the first and second nodes respectively.

Abstract: Provided are a variable field effect transistor (FET) designed to suppress a reduction of current between a source and a drain due to heat while decreasing a temperature of the FET, and an electrical and electronic apparatus including the variable gate FET. The variable gate FET includes a FET and a gate control device that is attached to a surface or a heat-generating portion of the FET and is connected to a gate terminal of the FET so as to vary a voltage of the gate terminal. A channel current between the source and drain is controlled by the gate control device that varies the voltage of the gate terminal when the temperature of the FET increases above a predetermined temperature.

Abstract: A semiconductor device includes: a semiconductor layer having a first end portion and a second end portion; a first main electrode provided on the first end portion and electrically connected to the semiconductor layer; a second main electrode provided on the second end portion and electrically connected to the semiconductor layer; a first gate electrode provided via a first gate insulating film in a plurality of first trenches formed from the first end portion toward the second end portion; and a second gate electrode provided via a second gate insulating film in a plurality of second trenches formed from the second end portion toward the first end portion. Spacing between a plurality of the first gate electrodes and spacing between a plurality of the second gate electrodes are 200 nm or less.

Abstract: A semiconductor device includes a semiconductor substrate and a MOS transistor. The semiconductor substrate has the first main surface and the second main surface facing each other. The MOS transistor includes a gate electrode (5a) formed on the first main surface side, an emitter electrode (11) formed on the first main surface side, and a collector electrode (12) formed in contact with the second main surface. An element generates an electric field in a channel by a voltage applied to the gate electrode (5a), and controls the current between the emitter electrode (11) and the collector electrode (12) by the electric field in the channel. The spike density in the interface between the semiconductor substrate and the collector electrode (12) is not less than 0 and not more than 3×108 unit/cm2. Consequently, a semiconductor device suitable for parallel operation is provided.

Abstract: A bidirectional electrostatic discharge (ESD) protection device includes a substrate having a topside semiconductor surface that includes a first silicon controlled rectifier (SCR) and a second SCR formed therein including a patterned p-buried layer (PBL) including a plurality of PBL regions. The first SCR includes a first and second n-channel remote drain MOS device each having a gate, a source within a p-body, and sharing a first merged drain. The second SCR includes a third and a fourth n-channel remote drain MOS device each having a gate, a source within a p-body, and sharing a second merged drain. The plurality of PBL regions are directly under at least a portion of the sources while being excluded from being directly under either of the merged drains.

Abstract: Device structures, design structures, and fabrication methods for a drain-extended metal-oxide-semiconductor (DEMOS) transistor. A first well of a first conductivity type and a second well of a second conductivity type are formed in a device region. The first and second wells are juxtaposed to define a p-n junction. A first doped region of the first conductivity type and a doped region of the second conductivity type are in the first well. The first doped region of the first conductivity type is separated from the second well by a first portion of the first well. The doped region of the second conductivity type is separated from the second well by a second portion of the first well. A second doped region of the first conductivity type, which is in the second well, is separated by a portion of the second well from the first and second portions of the first well.

Abstract: A semiconductor layer has a first layer of first conductive type, a second layer of second conductive type, and a third layer. The third layer has a first region of first conductive type, and a second region of second conductive type. A second electrode is in contact with each of the first and second regions. A trench is formed on the semiconductor layer at a surface opposite to its surface facing a first electrode. A gate electrode is embedded in the trench with a gate insulating film interposed therebetween. The gate electrode includes a first portion projecting into the first layer through the first region and the second layer, a second portion projecting into the first layer through the second region and the second layer. The second portion projects into the first layer deeper than a depth in which the first portion projects into the first layer.

Abstract: A semiconductor device provides a gate electrode formed on a lateral face of a wide trench, and thereby the gate electrode is covered by a gate insulating layer and a thick insulating layer to be an inter layer. Therefore, a parasitic capacitance of the gate becomes small, and there is no potential variation of the gate since there is no floating p-layer so that a controllability of the dv/dt can be improved. In addition, the conductive layer between the gate electrodes can relax the electric field applied to the corner of the gate electrode. In consequence, compatibility of low loss and low noise and high reliability can be achieved.

Abstract: High power wide band-gap MOSFET-gated bipolar junction transistors (“MGT”) are provided that include a first wide band-gap bipolar junction transistor (“BJT”) having a first collector, a first emitter and a first base, a wide band-gap MOSFET having a source region that is configured to provide a current to the base of the first wide band-gap BJT and a second wide band-gap BJT having a second collector that is electrically connected to the first collector, a second emitter that is electrically connected to the first emitter, and a second base that is electrically connected to the first base.

Abstract: One embodiment of the disclosure provides an electrostatic discharge protection circuit. The electrostatic discharge protection circuit includes a p-type field effect transistor, a capacitance device and an n-type field effect transistor. The p-type field effect transistor has a source coupled to an input/output terminal, a gate coupled to a first node and a drain coupled to a second node. The capacitance device has a first terminal coupled to a first rail and a second terminal coupled to the first node. The n-type field effect transistor has a source coupled to the first rail, a gate coupled to the second node and a drain coupled to the first node.

Abstract: A semiconductor switch comprises a PNPN structure arranged to provide an SCR-like functionality, and a MOS gate structure, preferably integrated on a common substrate. The switch includes ohmic contacts for the MOS gate, and for the cathode and gate regions of the PNPN structure; the anode contact is intrinsic. A fixed voltage is typically applied to an external node. The MOS gate structure allows current to be conducted between the external node and the intrinsic anode when on, and the PNPN structure conducts the current from the anode to the cathode when an appropriate voltage is applied to the gate contact. Regenerative feedback keeps the switch on once it begins to conduct. The MOS gate inhibits the flow of current between the external node and anode—and thereby turns off the switch—when off. When on, the MOS gate's channel resistance serves as a ballast resistor.

Abstract: Provided are a variable field effect transistor (FET) designed to suppress a reduction of current between a source and a drain due to heat while decreasing a temperature of the FET, and an electrical and electronic apparatus including the variable gate FET. The variable gate FET includes a FET and a gate control device that is attached to a surface or a heat-generating portion of the FET and is connected to a gate terminal of the FET so as to vary a voltage of the gate terminal. A channel current between the source and drain is controlled by the gate control device that varies the voltage of the gate terminal when the temperature of the FET increases above a predetermined temperature.

Abstract: In one embodiment, a semiconductor device is formed in a body of semiconductor material. The semiconductor device includes a charge compensating trench formed in proximity to active portions of the device. The charge compensating trench includes a trench filled with various layers of semiconductor material including opposite conductivity type layers.