Abstract: A semiconductor device of the RESURF type with a "low-side" lateral DMOST (LDMOST), comprising a semiconductor body (1) of predominantly a first conductivity type and a surface region (3) adjoining a surface (2) and of a second conductivity type. The LDMOST comprises a back gate region (5) of the first conductivity type provided in the surface region (3) with a source region (6) of the second conductivity type in the back gate region (5) and a channel region (7) defined between the source region (6) and an edge of the back gate region (5). A drain region (8) of the second conductivity type is present at a distance from the back gate region (5). A separation region (15) of the first conductivity type is provided around the LDMOST in the surface region (3), which separation region adjoins the surface (2) and extends towards the semiconductor body (1).

Abstract: An insulated gate bipolar transistor has a reverse conducting function built therein. A semiconductor layer of a first conduction type is formed on the side of a drain, a semiconductor layer of a second conduction type for causing conductivity modulation upon carrier injection is formed on the semiconductor layer of the first conduction type, a semiconductor layer of the second conduction type for taking out a reverse conducting current opposite in direction to a drain current is formed in the semiconductor layer of the second conduction type which is electrically connected to a drain electrode, and a semiconductor layer of the second conduction type is formed at or in the vicinity of a pn junction, through which carriers are given and received to cause conductivity modulation, with a high impurity concentration resulting in a path for the reverse conducting current into a pattern not impeding the passage of the carriers.

Abstract: A semiconductor device includes a semiconductor body (1, 2) with an island-shaped region (3) adjoining the surface, in which a contact pad (6) is provided above the island-shaped region (3) and separated therefrom by an insulating layer (5). The island-shaped region (3) forms a pn-junction (34) with an adjoining isolating region (4). According to the invention, the device is provided with regions (40, 41) for increasing the breakdown voltage of the pn-junction (34).

Abstract: For a vertical DMOS power transistor or a high voltage bipolar transistor, an edge termination at the perimeter of the die surrounding the active transistor cells includes multiple spaced apart field rings. A trench is located between each adjacent pair of field rings and is insulated either by oxide formed on the sidewalls thereof or by an oxide filling. The insulated trenches allow the field rings to be very closely spaced together. Advantageously the trenches may be formed in the same process steps as are the trenched gate electrodes of the active portion of the transistor. This structure eliminates the necessity for fabricating thick field oxide underlying a conventional field plate termination, and hence allows fabrication of a transistor without the need for a field plate termination, and in which the multiple field rings are suitable for a transistor device having a breakdown voltage in the range of 20 to 150 volts.

Abstract: A diode implemented in a junction isolated process protected from minority carrier substrate injection is disclosed. In a preferred embodiment, a diode includes an N+ cathode region and a P+ anode region formed in a P epitaxial region, and an N+ isolation region enclosing the epitaxial region. A CMOS inverter connected to the cathode region shorts the isolation region to either the cathode or the grounded substrate, depending on the voltage at the cathode, and thereby prevents minority carrier injection into the substrate in all conditions.

Abstract: A high voltage semiconductor structure (10) includes a semiconductor substrate (11) of a first conductivity type. The structure (10) also includes a first region (12) providing a main rectifying junction, a second region (13, 17, 21) of a second conductivity type formed in the semiconductor substrate and surrounding the first region ( 12 ) and a third region (14, 18, 22) of the second conductivity type. The third region (14, 18, 22) has reduced conductivity and greater junction depth compared to the second region (13, 17, 21). The third region (14, 18, 22) surrounds and is in contact with the second region (13, 17, 21) to form field rings which improve (increase) breakdown voltage of the high voltage semiconductor structure (10).

Abstract: A semiconductor body (2) has adjacent a first major surface (3) a first region (5) of one conductivity type part of which defines an active device area (6) of a power semiconductor device (7) having at least two electrodes (8 and 9 or 8 and 10) and active device regions (11) each forming with the first region (5) a pn junction (11a) extending to the first major surface (3). A protection device (12) formed by a series-connected array of semiconductor rectifying elements (13) is provided on an insulating layer (14) on the first major surface (3). The protection device (12) is connected between at least two electrodes (8 and 9 or 10) of the power semiconductor device (7) so as to break down to cause conduction between the two electrodes when the voltage across the protection device (12) exceeds a predetermined limit.

Abstract: It is usual in high-voltage integrated circuits to provide one or several breakdown-voltage-raising rings at the edge of a high-voltage island in the form of surface zones of the conductivity type opposite to that of the island. According to the invention, the function of these rings is locally taken over by one or several zones forming part of a circuit element and also provided with a breakdown-voltage-raising edge. Since the breakdown-voltage-raising zones are locally omitted alongside the island insulation, a major space saving can be achieved.

Abstract: Conductive plates (16a-16e), or floating semiconductor regions (17a-17d), or conductive plates (16a, 16c, 16e) and floating semiconductor regions (17a, 17d) are disposed in alignment so that a coupling capacitance between the conductive plates and/or the floating semiconductor regions which are adjacent to each other decrease as a distance from a first or second semiconductor region (12, 13) increases. Therefore, the respective potentials at the conductive plates or the floating semiconductor regions can be varied linearly (or at equal potential differences), and corresponding potential distribution can be achieved on the surface of a semiconductor substrate (11). As a result, electric field concentration on the surface of the semiconductor substrate (11) just under a high potential conductive layer (14) can be prevented effectively even by the use of an insulating layer (15) with a common thickness.

Abstract: In a power FET composed of a substrate having upper and lower surfaces and having a semiconductor body providing a current flow path between the upper and lower surfaces and having at least one body region of a first conductivity type which extends to said upper surface; and at least one base region extending into the substrate from the upper surface, the base region being of a second conductivity type opposite to the first conductivity type, the base region being at least partially disposed in the current flow path and having at least two portions between which the at least one body region extends, and the FET further having an insulated gate disposed at the upper surface above the body region, the substrate further has a shielding region of the second conductivity type extending into the at least one body region from the upper surface, at a location below the gate electrode and enclosed by the base region portions, and spaced from the base region by parts of the body region of the first conductivity type.

Abstract: A silicon carbide power MOSFET device includes a first silicon carbide layer, epitaxially formed on the silicon carbide substrate of opposite conductivity type. A second silicon carbide layer of the same conductivity type as the substrate is formed on the first silicon carbide layer. A power field effect transistor is formed in the device region of the substrate and in the first and second silicon carbide layers thereover. At least one termination trench is formed in the termination region of the silicon carbide substrate, extending through the first and second silicon carbide layers thereover. The termination trench defines one or more isolated mesas in the termination region which act as floating field rings. The termination trenches are preferably insulator lined and filled with conductive material to form floating field plates. The outermost trench may be a deep trench which extends through the first and second silicon carbide layers and through the drift region of the silicon carbide substrate.

Abstract: A first device region (10) of one conductivity type adjacent one major surface (1a) of a semiconductor body (1) has a relatively highly doped subsidiary region (11) spaced from the one major surface (1a) by a relatively lowly doped subsidiary region (12). A second device region (20) of the opposite conductivity type within the subsidiary region (12) has an intrinsic subsidiary region (21) and an extrinsic subsidiary region (23,24) surrounding the intrinsic subsidiary region (21) forming respective first and second pn junctions (22,25) with the relatively lowly doped subsidiary region (12). A third device region (30) of the one conductivity type is formed within the intrinsic subsidiary region (21) surface (1a).

Abstract: A semiconductor body (100) has a first device region (20) of one conductivity type forming with a second device region (13) of the opposite conductivity type provided adjacent one major surface (11) of the semiconductor body (100) a first pn junction (40) which is reverse-biassed in at least one mode of operation. A floating further region (50) of the opposite conductivity type is provided within the first device region (20) remote from the major surfaces (11 and 12) of the semiconductor body (100) and spaced from the second device region (13) so that, in the one mode, the depletion region of the first pn junction (40) reaches the floating further region (50) before the first pn junction (40) breaks down.

Abstract: A metal-oxide-semiconductor field effect transistor constructed in a trench or groove configuration is provided with protection against voltage breakdown by the formation of a shield region adjacent to the insulating layer which borders the gate of the transistor. The shield region is either more lightly doped than, or has a conductivity opposite to, that of the region in which it is formed, normally the drift or drain region, and it is formed adjacent to a corner on the boundary between the insulating layer and the drift or drain region, where voltage breakdown is most likely to occur.