Abstract: An array of power transistors on a semiconductor chip has serpentine gates separated by alternating source and drain regions. The gates combine rounded ends and rectangular sections joining the rounded ends. This geometry allows the metallization, in which the upper and lower metal layers are substantially congruent with each other, to have a design width that can be increased or decreased with the changes in width matched by the length of the rectangular sections thus allowing flexibility in the design of the power transistors.

Abstract: A structure for a thin film transistor LCD includes a data line extending in a first direction; a source electrode protruded for a predetermined length from the data line; a gate electrode in a second direction so as to be overlapped with a portion of the source electrode and the data line; and a drain electrode of which a portion is overlapped with the gate electrode. The drain electrode is bent according to the contours of the data line and the source so that wider channel can be obtained even without increasing the width of the gate electrode. A pixel electrode is connected to a region of the drain which is not overlapped with the gate electrode and positioned at the inner side of the region forming the data line and the gate electrode.

Abstract: An integrated circuit device includes a substrate including a trench therein and a conductive plug wire pattern in the trench. The conductive plug wire pattern includes a recessed portion that exposes portions of opposing sidewalls of the trench, and an integral plug portion that protrudes from a surface of the recessed portion to provide an electrical connection to at least one other conductive wire pattern on a different level of metallization. A surface of the plug portion may protrude to a substantially same level as a surface of the substrate adjacent to and outside the trench, and the surface of the recessed portion may be below the surface of the substrate outside the trench. Related fabrication methods are also discussed.

Abstract: Provided is a semiconductor device including a semiconductor chip, a film (first film) which is provided so as to cover an active region with a peripheral portion of the semiconductor chip being uncovered, and is made of a dielectric material having a low dielectric constant, and a package molding resin (sealing resin) provided so as to cover the semiconductor chip and the film. As a result, deterioration in contact property with the sealing resin is suppressed and a high frequency characteristic can be enhanced.

Abstract: The specification describes an improved mechanical electrode structure for MOS transistor devices with elongated runners. It recognizes that shrinking the geometry increases the likelihood of mechanical failure of comb electrode geometries. The mechanical integrity of a comb electrode is improved by interconnecting the electrode fingers in a cross-connected grid. In one embodiment, the transistor device is interconnected with gate fingers on a lower metaliization level, typically the first level metal, with the drain interconnected at a higher metal level. That allows the drain fingers to be cross-connected with a vertical separation between drain and gate comb electrodes. The cross-connect members may be further stabilized by adding beam extensions to the cross-connect members. The beam extensions may be anchored in an interlevel dielectric layer for additional support.

Abstract: An RF power transistor with a metal design (70) comprises a drain pad (72) and a plurality of metal drain fingers (74) extending from the drain pad, wherein at least one metal drain finger comprises one or more sections of metal (74-1, 74-2, 100-1, 100-2, 100-3), each section of metal including of one or more branch (54-1, 54-2, 116-1, 116-2, 116-11, 116-21, 116-41) of metal having a metal width maintained within a bamboo regime.

Abstract: According to the present invention, there is provided a semiconductor device having: first and second fins formed on a semiconductor substrate to oppose each other, and made of a semiconductor layer; an active region which is formed on the semiconductor substrate so as to be connected to the first and second fins, and supplies a predetermined voltage to the first and second fins; and a gate electrode formed on an insulating film formed on the semiconductor substrate, in a position separated from the active region by a predetermined spacing, so as to cross the first and second fins, wherein in the active region, a predetermined portion between a first portion connected to the first fin and a second portion connected to the second fin is removed.

Abstract: A semiconductor structure includes a semiconductor layer that includes an inverted V shaped channel region that allows avoidance of a raised source/drain region within the semiconductor structure. In one embodiment, a generally conventional gate electrode is located over a planar surface of the semiconductor layer over the inverted V shaped channel region. In another embodiment, the foregoing generally conventional gate electrode is used in conjunction with an inverted V shaped gate electrode that is located within an inverted V shaped notch that comprises the inverted V shaped channel region.

Abstract: There is provided a thin-film transistor that is formed on an insulating substrate, is capable of a high-speed operation, has small non-uniformity among devices, is hardly susceptible to device destruction due to high voltage, and is free from the effect of a parasitic transistor that forms at an edge part of an Si island. The thin-film semiconductor device is formed using a thin-film semiconductor provided on the insulating substrate and includes a gate region for formation of a channel region through which a drain current flows. The gate region has a ring shape in plan on the insulating substrate. High concentration impurity-doped regions are dividedly provided on an inside and an outside of the ring-shaped gate region, and the channel region is formed of a plurality of fan-shaped semiconductor single-crystal portions.

Abstract: The present invention, which aims to provide a gallium arsenide field-effect transistor that can reduce degradation of field-effect transistor characteristics, and to realize miniaturization of the transistor, includes: a substrate; a mesa which includes a channel layer and is formed on the substrate; a source electrode formed on the mesa; a drain electrode; and a gate electrode, wherein, on the mesa, a top pattern is formed in which finger portions of the source electrode and the drain electrode which are formed in comb-shape are located so as to interdigitate, and a gate electrode is formed between the source electrode and the drain electrode, while common portions, which are base parts of the finger portions of the source and drain electrodes, are formed on the surface of the mesa, and the part located below the straight portion which is parallel to the finger portions of the gate electrode is electrically separated from the part located below a corner portion that connects neighboring straight portions of

Abstract: The invention relates to a manufacturing method for an insulated gate semiconductor device cell, comprising the steps of forming a cell window (3) in a layered structure that is located on top of a semiconductor substrate (1), forming at least one process mask that partially covers the cell window (3). In forming the cell window (3), at least one strip (41, 42) of the layered structure is left to remain inside the cell window (3) and at least one strip (41, 42) is used to serve as an edge for the at least one process mask (51, 52). The invention further relates to an insulated gate semiconductor device, comprising a semiconductor substrate (1) having an essentially planar top surface and an insulated gate formed on the top surface by a layered structure (2) that comprises at least one electrically insulating layer (22), wherein at least one strip (41, 42) of the layered structure (2) is disposed on a third area of the top surface between an edge of the insulated gate and a first main contact (6).

Abstract: Segmented power transistors and fabrication methods are disclosed in which transistor segments are spaced from one another to facilitate thermal diffusion, and in which other electrical devices can be formed in the spaces between transistor segments.

Abstract: A semiconductor structure includes a silicon substrate of a first conductivity type including wells of a second conductivity type formed on a surface thereof. The wells may be laterally isolated by shallow trench isolation. Transistors are formed in the wells by first forming several chemically distinct layers. Anisotropic etching then forms openings in a top one of the layers. A blanket dielectric layer is formed in the openings and on the layers. Anisotropic etching removes portions of the blanket dielectric layer from planar surfaces of the substrate but not from sidewalls of the openings to form dielectric spacers separated by gaps within the openings. Gate oxides are formed by oxidation of exposed areas of the substrate. Ion implantation forms channels beneath the gate oxides. Polysilicon deposition followed by chemical-mechanical polishing defines gates in the gaps. The chemically distinct layers are then stripped without removing the dielectric spacers.