A method of forming a substrate contact in a vertical transistor device includes patterning a sacrificial layer to form an opening in the sacrificial layer, the sacrificial layer disposed on hardmask arranged on a substrate, and the substrate including a bulk semiconductor layer, a buried oxide layer arranged on the bulk semiconductor layer, and a semiconductor layer arranged on the buried oxide layer; forming oxide spacers on sidewalls of the opening in the sacrificial layer; using the oxide spacers as a pattern to etch a trench through the substrate, the trench stopping at a region within the bulk semiconductor layer; and depositing a conductive material in the trench to form the substrate contact.

In some examples, a transistor includes a drain, a channel, and a gate. The channel surrounds the drain and has a channel length to width ratio. The gate is over the channel to provide an active channel region that has an active channel region length to width ratio that is greater than the channel length to width ratio.

Prior known static random access memory (SRAM) cells are required that a diffusion layer be bent into a key-like shape in order to make electrical contact with a substrate with a P-type well region formed therein, which would result in a decrease in asymmetry leading to occurrence of a problem as to the difficulty in micro-patterning. To avoid this problem, the P-type well region in which an inverter making up an SRAM cell is formed is subdivided into two portions, which are disposed on the opposite sides of an N-type well region NW1 and are formed so that a diffusion layer forming a transistor has no curvature while causing the layout direction to run in a direction parallel to well boundary lines and bit lines. At intermediate locations of an array, regions for use in supplying power to the substrate are formed in parallel to word lines in such a manner that one regions is provided per group of thirty two memory cell rows or sixty four cell rows.

A method of forming a substrate contact in a vertical transistor device includes patterning a sacrificial layer to form an opening in the sacrificial layer, the sacrificial layer disposed on hardmask arranged on a substrate, and the substrate including a bulk semiconductor layer, a buried oxide layer arranged on the bulk semiconductor layer, and a semiconductor layer arranged on the buried oxide layer; forming oxide spacers on sidewalls of the opening in the sacrificial layer; using the oxide spacers as a pattern to etch a trench through the substrate, the trench stopping at a region within the bulk semiconductor layer; and depositing a conductive material in the trench to form the substrate contact.

Prior known static random access memory (SRAM) cells are required that a diffusion layer be bent into a key-like shape in order to make electrical contact with a substrate with a P-type well region formed therein, which would result in a decrease in asymmetry leading to occurrence of a problem as to the difficulty in micro-patterning. To avoid this problem, the P-type well region in which an inverter making up an SRAM cell is formed is subdivided into two portions, which are disposed on the opposite sides of an N-type well region NW1 and are formed so that a diffusion layer forming a transistor has no curvature while causing the layout direction to run in a direction parallel to well boundary lines and bit lines. At intermediate locations of an array, regions for use in supplying power to the substrate are formed in parallel to word lines in such a manner that one regions is provided per group of thirty two memory cell rows or sixty four cell rows.

The invention provides a body-contact metal-oxide-semiconductor field effect transistor (MOSFET) device. The body-contact MOSFET device includes a substrate. An active region is disposed on the substrate. A gate strip is extended along a first direction disposed on a first portion of the active region. A source doped region and a drain doped region are disposed on a second portion and a third portion of the active region, adjacent to opposite sides of the gate strip. The opposite sides of the gate strip are extended along the first direction. A body-contact doped region is disposed on a fourth portion of the active region. The body-contact doped region is separated from the gate strip by a fifth portion of the active region. The fifth portion is not covered by any silicide features.

In some examples, a transistor includes a drain, a channel, and a gate. The channel surrounds the drain and has a channel length to width ratio. The gate is over the channel to provide an active channel region that has an active channel region length to width ratio that is greater than the channel length to width ratio.

A vertical, high-voltage MOS transistor, which has a source region, a body contact region, and a number of trenches structures with field plates, and a method of forming the MOS transistor increase the on-state resistance of the MOS transistor by reducing the trench pitch. Trench pitch can be reduced with metal contacts that simultaneously touch the source regions, the body contact regions, and the field plates. Trench pitch can also be reduced with a gate that increases the size of the LDD region.

Disclosed are a receiver control circuit and a terminal. The receiver control circuit includes: a smart power amplifier module, a coder-decoder, and a receiver. The smart power amplifier module is electrically connected to the receiver by a first switch module. The first switch module includes a first switch component unit that is formed by a metal oxide semiconductor field-effect transistor (MOSFET). The first switch module further includes a first follower unit, where the first follower unit is configured to keep an unchanged voltage difference between a gate electrode of the MOSFET of the first switch component unit and a drain electrode thereof, and a gate electrode voltage of the MOSFET of the first switch component unit is greater than a drain electrode voltage thereof. The coder-decoder is electrically connected to the receiver by the second switch module. The second switch module includes a second switch component unit.

There is provided a semiconductor device comprising at least, a crystalline oxide semiconductor layer which has a band gap of 4.5 eV or more; and a field-effect mobility of 10 cm.sup.2/V.Math.s or higher.