Abstract: A device includes an array of cells, the source regions of the individual cells comprising a plurality of source region branches each extending towards a source region branch of an adjacent cell, the base regions of the individual cells comprising a corresponding plurality of base region branches merging together to form a single base region surrounding the source regions. The junctions between the merged base region and the drain region define rounded current conduction path areas for the on-state of the device between adjacent cells. Floating voltage regions of opposite conductivity type to the drain region are buried in the substrate beneath the merged base region. The features of the floating voltage regions define rings of the opposite conductivity type to the drain region that surround the current conduction paths of respective cells. The floating voltage regions include respective islands situated within the current conduction paths.

Abstract: A p-type body region and an n-type buffer region are formed on an n? drift region. An n++ emitter region and a p++ contact region are formed on the p-type body region in contact with each other. A p++ collector region is formed on the n-type buffer region. An insulating film is formed on the n? drift region, and a gate insulating film is formed on the n++ emitter region, the p-type body region, and the n drift region. A gate electrode is formed on the insulating film and the gate insulating film. A p+ low-resistivity region is formed in the p-type body region and surrounding the interface between the n++ emitter region and between the p-type body region and the p++ contact region. The p-type body region has two local maxima of an impurity concentration profile at the interface between the body region and the gate insulating film.

Abstract: According to one embodiment, a power semiconductor device includes a first insulating film and a second insulating film. The first insulating film has a first dielectric constant and is formed on a bottom surface and a side surface of a trench formed by a second semiconductor layer. The trench is in contact with a fourth semiconductor layer and extends from a surface of the fourth semiconductor layer through a third semiconductor layer to the second semiconductor layer. The second insulating film is formed on a side surface of the trench formed by the third semiconductor layer and a side surface of the trench formed by the fourth semiconductor layer, being connected to the first insulating film. The second insulating film has a second dielectric constant higher than the first dielectric constant. The gate electrode is buried in the trench via the first and second insulating films.

Abstract: A semiconductor structure includes a semiconductor substrate of a first conductivity type; a pre-high-voltage well (pre-HVW) in the semiconductor substrate, wherein the pre-HVW is of a second conductivity type opposite the first conductivity type; a high-voltage well (HVW) over the pre-HVW, wherein the HVW is of the second conductivity type; a field ring in the HVW and occupying a top portion of the HVW, wherein the field ring is of the first conductivity type; an insulation region over and in contact with the field ring and a portion of the HVW; a gate electrode partially over the insulation region; a drain region in the HVW, wherein the drain region is of the second conductivity type; and wherein the HVW horizontally extends further toward the drain region than the pre-HVW; and a source region adjacent to, and on an opposite side of the gate electrode than the drain region.

Abstract: A power semiconductor device includes a semiconductor body. The semiconductor body includes a body region of a first conductivity type for forming therein a conductive channel of a second conductivity type; a gate electrode arranged next to the body region; and a floating electrode arranged between the gate electrode and the body region.

Abstract: A semiconductor device includes: a semiconductor substrate of silicon carbide of a first conductivity type; a silicon carbide epitaxial layer of the first conductivity type, which has been grown on the principal surface of the substrate; well regions of a second conductivity type, which form parts of the silicon carbide epitaxial layer; and source regions of the first conductivity type, which form respective parts of the well regions. A channel epitaxial layer of silicon carbide is grown over the well regions and source regions of the silicon carbide epitaxial layer. A portion of the channel epitaxial layer located over the well regions functions as a channel region. A dopant of the first conductivity type is implanted into the other portions and of the channel epitaxial layer except the channel region.

Abstract: An integrated circuit device comprising a diode and a method of making an integrated circuit device comprising a diode are provided. The diode can comprise an island of a first conductivity type, a first region of a second conductivity type formed in the island, and a cathode diffusion contact region doped to the second conductivity type disposed in the first region. The diode can also comprise a cathode contact electrically contacting the cathode diffusion contact region, an anode disposed in the island, an anode contact electrically contacting the anode, and a first extension region doped to the first conductivity type disposed at a surface junction between the first region and the island.

Abstract: A lateral power MOSFET with a low specific on-resistance is described. Stacked P-top and N-grade regions in patterns of articulated circular arcs separate the source and drain of the transistor.

Abstract: A semiconductor structure includes a semiconductor substrate of a first conductivity type; a pre-high-voltage well (pre-HVW) in the semiconductor substrate, wherein the pre-HVW is of a second conductivity type opposite the first conductivity type; a high-voltage well (HVW) over the pre-HVW, wherein the HVW is of the second conductivity type; a field ring of the first conductivity type occupying a top portion of the HVW, wherein at least one of the pre-HVW, the HVW, and the field ring comprises at least two tunnels; an insulation region over the field ring and a portion of the HVW; a drain region in the HVW and adjacent the insulation region; a gate electrode over a portion the insulation region; and a source region on an opposite side of the gate electrode than the drain region.

Abstract: In one embodiment, a semiconductor device is formed having vertical localized charge-compensated trenches, trench control regions, and sub-surface doped layers. The vertical localized charge-compensated trenches include at least a pair of opposite conductivity type semiconductor layers. The trench control regions are configured to provide a generally vertical channel region electrically coupling source regions to the sub-surface doped layers. The sub-surface doped layers are further configured to electrically connect the drain-end of the channel to the vertical localized charge compensation trenches. Body regions are configured to isolate the sub-surface doped layers from the surface of the device.

Abstract: A semiconductor device includes a source, a drain, and a gate configured to selectively enable a current to pass between the source and the drain. The semiconductor device includes a drift zone between the source and the drain and a first field plate adjacent the drift zone. The semiconductor device includes a dielectric layer electrically isolating the first field plate from the drift zone and charges within the dielectric layer close to an interface of the dielectric layer adjacent the drift zone.

Abstract: A dielectric material layer is formed on a bottom surface and sidewalls of a trench in a semiconductor substrate. The silicon oxide layer forms a drift region dielectric on which a field plate is formed. Shallow trench isolation may be formed prior to formation of the drift region dielectric, or may be formed utilizing the same processing steps as the formation of the drift region dielectric. A gate dielectric layer is formed on exposed semiconductor surfaces and a gate conductor layer is formed on the gate dielectric layer and the drift region dielectric. The field plate may be electrically tied to the gate electrode, may be an independent electrode having an external bias, or may be a floating electrode. The field plate biases the drift region to enhance performance and extend allowable operating voltage of a lateral diffusion field effect transistor during operation.

Abstract: In one embodiment, a device is formed in a region of semiconductor material. The device includes active cell trenches and termination trenches each having doped sidewall surfaces that compensate the region of semiconductor material during reverse bias conditions to form a superjunction structure. The termination trenches include a trench fill material that enhances depletion region spread during reverse bias conditions.

Abstract: A semiconductor die has devices such as MOSgated devices, diodes and the like formed into the top and bottom surfaces of the die. One terminal of each of the devices terminal in the interior center of the die and a common contact is made to the interior center of the die at one edge of the die. Various packages for the die having a reduced foot print on a support substrate are disclosed.

Abstract: In one embodiment, silicide layers are formed on two oppositely doped adjacent semiconductor regions. A conductor material is formed electrically contacting both of the two silicides.

Abstract: A structure and method of forming a body contact for a semiconductor-on-insulator trench device. The method including: forming set of mandrels on a top surface of a substrate, each mandrel of the set of mandrels arranged on a different corner of a polygon and extending above the top surface of the substrate, a number of mandrels in the set of mandrels equal to a number of corners of the polygon; forming sidewall spacers on sidewalls of each mandrel of the set of mandrels, sidewalls spacers of each adjacent pair of mandrels merging with each other and forming a unbroken wall defining an opening in an interior region of the polygon, a region of the substrate exposed in the opening; etching a contact trench in the substrate in the opening; and filling the contact trench with an electrically conductive material to form the contact.

Abstract: A structure of power semiconductor device integrated with clamp diodes having separated gate metal pad is disclosed. The separated gate metal pads are wire bonded together on the gate lead frame. This improved structure can prevent the degradation of breakdown voltage due to electric field in termination region blocked by polysilicon.

Abstract: A power semiconductor element having a lightly doped drift and buffer layer is disclosed. One embodiment has, underneath and between deep well regions of a first conductivity type, a lightly doped drift and buffer layer of a second conductivity type. The drift and buffer layer has a minimum vertical extension between a drain contact layer on the adjacent surface of a semiconductor substrate and the bottom of the deepest well region which is at least equal to a minimum lateral distance between the deep well regions. The vertical extension can also be determined such that a total amount of dopant per unit area in the drift and buffer layer is larger than a breakdown charge amount at breakdown voltage.

Abstract: A super-junction semiconductor substrate is configured in such a manner that an n-type semiconductor layer of a parallel pn structure is opposed to a boundary region between an active area and a peripheral breakdown-resistant structure area. A high-concentration region is formed at the center between p-type semiconductor layers that are located on both sides of the above n-type semiconductor layer. A region where a source electrode is in contact with a channel layer is formed over the n-type semiconductor layer. A portion where the high-concentration region is in contact with the channel layer functions as a diode. The breakdown voltage of the diode is set lower than that of the device.

Abstract: A semiconductor structure includes a semiconductor substrate; a first high-voltage well (HVW) region of a first conductivity type overlying the semiconductor substrate; a second HVW region of a second conductivity type opposite the first conductivity type overlying the substrate and laterally adjoining the first HVW region; a gate dielectric extending from over the first HVW region to over the second HVW region; a gate electrode on the gate dielectric; a drain region in the second HVW region; a source region at an opposite side of the gate dielectric than the drain region; and a deep well region of the first conductivity type underlying the second HVW region. Substantially no deep well region is formed directly underlying the drain region.

Abstract: An RF field effect transistor has a gate electrode, and comb shaped drain and source electrodes, fingers of the comb shaped drain being arranged to be interleaved with fingers of the source electrode, the source and drain electrodes having multiple layers (110,120,130,140). An amount of the interleaving is different in each layer, to enable optimization, particularly for low parasitic capacitance without losing all the advantage of low current density provided by the multiple layers. The interleaving is reduced for layers further from the gate electrode by having shorter fingers. The reduction in interleaving can be optimized for minimum capacitance, by a steeper reduction in interleaving, or for minimum lateral current densities in source and drain fingers, by a more gradual reduction in interleaving. This can enable operation at higher temperatures or at higher input bias currents, while still meeting the requirements of electro-migration rules.

Abstract: A hybrid integrated circuit device having high mount reliability comprises a module substrate which is a ceramic wiring substrate, a plurality of electronic component parts laid out on the main surface of the module substrate, a plurality of electrode terminals laid out on the rear surface of the module substrate, and a cap which is fixed to the module substrate to cover the main surface of the module substrate. The electrode terminals include a plurality of electrode terminals which are aligned along the edges of the module substrate and power voltage supply terminals which are located inner than these electrode terminals. The electrode terminals aligned along the substrate edges are coated, at least in their portions close to the substrate edge, with a protection film having a thickness of several tens micrometers or less. Connection reinforcing terminals consist of a plurality of divided terminals which are independent of each other, and are ground terminals.

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.

Abstract: A MOS device includes a semiconductor substrate having a first conductive type, a source region, a gate structure, and a drain region having a second conductive type. The gate structure is formed on the semiconductor substrate and substantially parallel to a first direction. The source region and the drain region are both disposed in the semiconductor substrate, and on two opposite sides of the gate structure. The source region includes at least a source doped region having the second conductive type, and at least a source contact region having the first conductive type, and the source doped region and the source contact region are alternately arranged along the first direction.

Abstract: A single crystal semiconductor layer of a first conduction type is disposed on a surface of a semiconductor substrate. A plurality of trenches are provided in the semiconductor layer to form a plurality of first semiconductor regions of the first conduction type at intervals in a direction parallel to the surface. An epitaxial layer is buried in the plurality of trenches to form a plurality of second semiconductor regions of a second conduction type. The plurality of second semiconductor regions each includes an outer portion with a high impurity concentration formed against an inner wall of the trench, and an inner portion with a low impurity concentration formed inner than the outer portion.

Abstract: A phase change memory device resistant to stack pattern collapse is presented. The phase change memory device includes a silicon substrate, switching elements, heaters, stack patterns, bit lines and word lines. The silicon substrate has a plurality of active areas. The switching elements are connected to the active areas. The heaters are connected to the switching elements. The stack patterns are connected to the heaters. The bit lines are connected to the stack patterns. The word lines are connected to the active areas of the silicon substrate.

Abstract: Semiconductor component including a drift region and a drift control region. One embodiment provides a drift zone and a drift control zone. A drift control zone dielectric is arranged between the first drift zone and the drift control zone and has at least two sections arranged at a distance from one another in a current flow direction of the component. At least one separating structure is arranged between the drift zone and the drift control zone in the region of an interruption, defined by the at least two sections, of the drift control zone dielectric and has at least one PN junction.

Abstract: The invention provides a semiconductor structure. A first type body doped region is deposited on a first type substrate. A first type heavily-doped region having a finger portion with an enlarged end region is deposited on the first type body doped region. A second type well region is deposited on the first type substrate. A second type heavily-doped region is deposited on the second type well region. An isolation structure is deposited between the first type heavily-doped region and the second type heavily-doped region. A gate structure is deposited on the first type substrate between the first type heavily-doped region and the isolation structure.

Abstract: A semiconductor device including a well region formed in a silicon substrate; a trench exposing a predetermined portion of the uppermost surface of the semiconductor substrate; a body layer formed in the semiconductor substrate at the trench; a device isolation layer formed in the well region; a gate insulating layer formed in the trench over the body layer; a gate electrode formed in the trench over the gate insulating layer and against the device isolation layer; a lightly doped drain region formed in the body layer; an insulating layer formed in the trench over the lightly doped drain region; a source region formed in the body layer; a drain region formed in the well region against the device isolation layer; and a body region formed in the body layer against the source region. The on-resistance can be reduced by forming the gate and source beneath the device isolating layer.

Abstract: A semiconductor device includes: a first semiconductor layer of a first conductivity type; a second semiconductor layer of the first conductivity type provided on a main surface of the first semiconductor layer and having a lower impurity concentration than that of the first semiconductor layer; a third semiconductor layer of a second conductivity type provided on the second semiconductor layer; a fourth semiconductor layer of the first conductivity type selectively provided on the third semiconductor layer; a gate electrode provided in a trench passing through the third semiconductor layer and reaching the second semiconductor layer; a first main electrode contacting the fourth semiconductor layer and contacting the third semiconductor layer through a contact groove provided to pass through the fourth semiconductor layer between the contiguous gate electrodes; a second main electrode provided on an opposite surface to the main surface of the first semiconductor layer; and a fifth semiconductor layer of the s

Abstract: A trench MOSFET with on-resistance reduction comprises a trenched gate surrounded by a source region encompassed in a body region above a drain region disposed on a bottom surface of a substrate, wherein the said MOSFET further comprises a plurality of source-body contact trenches opened relative to a top surface into said source and body regions and each of the source-body contact trenches is filled with a contact metal plug as a source-body contact; a insulation layer covered over the top of the trenched gate, the body region and the source region; a front metal layer formed on a top surface of the MOSFET; wherein a low-resistivity phosphorus substrate and retrograded P-body formed by medium or high energy Ion Implantation to reduce Rds contribution from substrate and drift region.

Abstract: A power semiconductor component includes a drift zone in a semiconductor body, a component junction and a compensation zone. The component junction is disposed between the drift zone and a further component zone, which is configured such that when a blocking voltage is applied to the component junction, a space charge zone forms extending generally in a first direction in the drift zone. The compensation zone is disposed adjacent to the drift zone in a second direction and includes at least one high-dielectric material having a temperature-dependent dielectric constant. The temperature dependence of the compensation zone varies in the second direction.

Abstract: A high-voltage semiconductor device includes a semiconductor layer having a plurality of pillars of a first conductivity type defined by a plurality of trenches which extend from a top surface of the semiconductor layer toward a bottom surface thereof. A charge compensation layer of a second conductivity type is disposed over at least sidewalls of each trench to a predetermined thickness to form a groove in each trench. A charge compensation plug of the first conductivity type substantially fills each groove.

Abstract: A semiconductor device having a junction barrier Schottky diode includes: a SiC substrate; a drift layer on the substrate; an insulation film on the drift layer having an opening in a cell region; a Schottky barrier diode having a Schottky electrode contacting the drift layer through the opening of the insulation film and an ohmic electrode on the substrate; a terminal structure having a RESURF layer surrounding the cell region; and multiple second conductive type layers on an inner side of the RESURF layer. The second conductive type layers and the drift layer provide a PN diode. The Schottky electrode includes a first Schottky electrode contacting the second conductive type layers with ohmic contact and a second Schottky electrode contacting the drift layer with Schottky contact.

Abstract: An integrated circuit comprises a first drain region having a symmetric shape across at least one of horizontal and vertical centerlines. A first gate region has a first shape that surrounds the first drain region. A second drain region has the symmetric shape. A second gate region has the first shape that surrounds the second drain region. A connecting gate region connects the first and second gate regions. A first source region is arranged adjacent to and on one side of the first gate region, the second gate region and the connecting gate region. A second source region is arranged adjacent to and on one side of side of the first gate region, the second gate region and the connecting gate region.

Abstract: In a lateral-type power MOSFET, high breakdown voltage is achieved with suppressing to increase a cell pitch, and a feedback capacity and an ON resistance are decreased. An n? type silicon region having a high resistance to be a region of maintaining a breakdown voltage is vertically provided with respect to a main surface of an n+ type silicon substrate, and the n? type silicon region having the high resistance is connected to the n+ type silicon substrate. Also, a conductive substance is filled through an insulating substance inside a trench formed to reach the n+ type silicon substrate from the main surface of the n+ type silicon substrate so as to contact with the n? type silicon region having the high resistance, and the conductive substance is electrically connected to a source electrode.

Abstract: The present invention relates to a power semiconductor device comprising a switching power semiconductor element, and a free wheeling diode in anti-parallel connection to the switching power semiconductor element. The power semiconductor is characterized in that a reverse electrode of the switching power semiconductor element and a reverse electrode of the free wheeling diode are bonded and mounted on a circuit pattern formed on the main surface of the first substrate, and that a circuit pattern, which is so formed on the main surface of the second substrate as to oppose a surface electrode of the switching power semiconductor element and a surface electrode of the free wheeling diode, is connected to the surface electrodes of the switching power semiconductor element and the free wheeling diode through connective conductors to be soldered, respectively.

Abstract: A semiconductor apparatus includes: a first first-conductivity-type semiconductor layer; a second first-conductivity-type semiconductor layer provided on a major surface of the first first-conductivity-type semiconductor layer; a third second-conductivity-type semiconductor layer forming a periodic array structure in combination with the second first-conductivity-type semiconductor layer in a lateral direction generally parallel to the major surface of the first first-conductivity-type semiconductor layer; and a sixth first-conductivity-type semiconductor layer provided on the major surface of the first first-conductivity-type semiconductor layer in a termination section outside the periodic array structure. The second first-conductivity-type semiconductor layer has an impurity concentration varying in the lateral direction and the impurity concentration is minimized at a center in the lateral direction.

Abstract: This invention aims at providing an inexpensive semiconductor device having a parasitic diode and lowering an hfe of a parasitic PNP transistor and a manufacturing method thereof. Such semiconductor device includes a P-type silicon substrate and a gate electrode formed above the P-type silicon substrate. The P-type silicon substrate includes an N-type well layer, an N-type buried layer, a P-type body layer, an N-type source layer formed in the P-type body layer, and a drain contact layer formed in the N-type well layer. The P-type body layer and the N-type source layer are formed by self alignment that uses the gate electrode as a mask. The N-type drain contact layer is formed opposite the N-type source layer across the P-type body layer formed below the gate electrode. The N-type buried layer is formed below the P-type body layer.

Abstract: A dual current path LDMOSFET transistor (40) is provided which includes a substrate (400), a graded buried layer (401), an epitaxial drift region (404) in which a drain region (416) is formed, a first well region (406) in which a source region (412) is formed, a gate electrode (420) formed adjacent to the source region (412) to define a first channel region (107), and a current routing structure that includes a buried RESURF layer (408) in ohmic contact with a second well region (414) formed in a predetermined upper region of the epitaxial layer (404) so as to be completely covered by the gate electrode (420), the current routing structure being spaced apart from the first well region (406) and from the drain region (416) on at least a side of the drain region to delineate separate current paths from the source region and through the epitaxial layer.

Abstract: A SiC semiconductor device includes: a substrate; a drift layer on the substrate; a trench on the drift layer; a base region in the drift layer sandwiching the trench; a channel between the base region and the trench; a source region in the base region sandwiching the trench via the channel; a gate electrode in the trench via a gate insulation film; a source electrode coupled with the source region; a drain electrode on the substrate opposite to the drift layer; and a bottom layer under the trench. An edge portion of the bottom layer under a corner of a bottom of the trench is deeper than a center portion of the bottom layer under a center portion of the bottom of the trench.

Abstract: A power semiconductor device includes: a first semiconductor layer of the first conduction type; second semiconductor layers of the first conduction type and third semiconductor layers of the second conduction type alternately provided transversely on the first semiconductor layer; fourth semiconductor layers of the second conduction type provided on the surfaces of the third semiconductor layers; fifth semiconductor layers of the first conduction type provided selectively on the surfaces of the fourth semiconductor layer; sixth semiconductor layers of the second conduction type and seventh semiconductor layers of the first conduction type alternately provided transversely on the second and the third semiconductor layers; a first main electrode electrically connected to the first semiconductor layer; an insulation film provided on the fourth semiconductor layers, the sixth semiconductor layers and the seventh semiconductor layers; a control electrode provided on the fourth semiconductor layers, the sixth semi

Abstract: A MOS transistor capable of withstanding significant currents, having doped areas corresponding to first and second main terminals of elementary MOS transistors and having, in top view, the shape of parallel strips separated by gate regions; first conductive elements which do not extend on the doped areas corresponding to the second main terminals and dividing into first fingers extending at least partly on the doped areas corresponding to the first main terminals and connected thereto; and second conductive elements which do not extend on the doped areas corresponding to the first main terminals and divide into second fingers extending at least partly on the doped areas corresponding to the second main terminals and connected thereto, the second fingers being at least partly intercalated with the first fingers.

Abstract: A lateral MISFET having a semiconductor body has a doped semiconductor substrate of a first conduction type and an epitaxial layer of a second conduction type, which is complementary to the first conduction type, the epitaxial layer being provided on the semiconductor substrate. This MISFET has, on the top side of the semiconductor body, a drain, a source, and a gate electrode with gate insulator. A semiconductor zone of the first conduction type is embedded in the epitaxial layer in a manner adjoining the gate insulator, a drift zone of the second conduction type being arranged between the semiconductor zone and the drain electrode in the epitaxial layer. The drift zone has pillar-type regions which are arranged in rows and columns and whose boundary layers have a metal layer which in each case forms a Schottky contact with the material of the drift zone.

Abstract: In one embodiment, a semiconductor device is formed in a body of semiconductor material. The semiconductor device includes a localized region of doping near a portion of a channel region where current exits during operation.

Abstract: A power semiconductor device includes: a second semiconductor layer of the first conductivity type and a third semiconductor layer of a second conductivity type formed on a first semiconductor layer and alternately arranged along at least one direction parallel to an upper face of the first semiconductor layer; a fourth semiconductor layer of the second conductivity type selectively formed in an upper face of the second and third semiconductor layers; and a control electrode formed above the second, third and fourth semiconductor layers via a gate insulating film. The control electrode includes: first portions periodically arranged along a first direction selected from arranging directions of the third semiconductor layer, the third semiconductor layer has a shortest arrangement period in the first direction, and second portions periodically arranged along a second direction, the second direction being parallel to the upper face of the first semiconductor layer and crossing the first direction.

Abstract: A semiconductor device having a JBS diode includes: a SiC substrate; a drift layer on the substrate; an insulation film on the drift layer having an opening in a cell region; a Schottky barrier diode having a Schottky electrode contacting the drift layer through the opening and an ohmic electrode on the substrate; a terminal structure having a RESURF layer in the drift layer surrounding the cell region; and multiple second conductive type layers in the drift layer on an inner side of the RESURF layer contacting the Schottky electrode. The second conductive type layers are separated from each other. The second conductive type layers and the drift layer provide a PN diode. Each second conductive type layer has a depth larger than the RESURF layer.

Abstract: A semiconductor device has a semiconductor body with a semiconductor device structure including at least a first electrode and a second electrode. Between the two electrodes, a drift region is arranged, the drift region including charge compensation zones and drift zones arranged substantially parallel to one another. At least one charge carrier storage region which is at least partially free of charge compensation zones is arranged in the semiconductor body.

Abstract: A semiconductor device package comprises a first semiconductor die having a first source region, a first gate region, and a first drain region attached on a first leadframe, a second semiconductor die having a second source region, a second gate region, and a second drain region attached on a second leadframe, and several pins electrically connected to the leadframes and source and gate regions. The second leadframe is electrically connected to the first source region. The pins connected to the first leadframe and second source region are on a side of the package, and the pins connected to the first gate region, second leadframe, and second gate region are on another side of the package.

Abstract: Reduced source resistance is realized in a laterally diffused MOS transistor by fabricating the transistor in a P-doped epitaxial layer on an N-doped semiconductor substrate and using a trench contact for ohmically connecting the N-doped source region to the N-doped substrate.