Abstract: A semiconductor device (102) that includes a drain extended PMOS transistor (CT1a) is provided, as well as fabrication methods (202) therefore. In forming the PMOS transistor, a drain (124) of the transistor is formed over a region (125) of a p-type upper epitaxial layer (106), where the region (125) of the p-type upper epitaxial layer (106) is sandwiched between a left P-WELL region (130a) and a right P-WELL region (130b) formed within the p-type upper epitaxial layer (106). The p-type upper epitaxial layer (106) is formed over a semiconductor body (104) that has an n-buried layer (108) formed therein. This arrangement serves to increase the breakdown voltage (BVdss) of the drain extended PMOS transistor.

Abstract: Semiconductor devices (102) and drain extended PMOS transistors (CT1a) are provided, as well as fabrication methods (202) therefor, in which a p-type separation region (130) is formed between an n-buried layer (108) and the transistor backgate (126) to increase breakdown voltage performance without increasing epitaxial thickness.

Abstract: Extended-drain MOS transistor devices and fabrication methods are provided, in which a drift region of a first conductivity type is formed between a drain of the first conductivity type and a channel. The drift region comprises first and second portions, the first portion extending partially under a gate structure between the channel and the second portion, and the second portion extending laterally between the first portion and the drain, wherein the first portion of the drift region has a concentration of first type dopants higher than the second portion.

Abstract: A semiconductor integrated circuit comprises contact pads located over active components, which are positioned to minimize the distance for power delivery between a selected pad and one or more corresponding active components, to which the power is to be delivered. This minimum distance further enhances dissipation of thermal energy released by the active components. More specifically, a semiconductor integrated circuit comprises a laterally organized power transistor, an array of power supply contact pads distributed over the transistor, means for providing a distributed, predominantly vertical current flow from the contact pads to the transistor, and means for connecting a power source to each of the contact pads. Positioning the power supply contact pads directly over the active power transistor further saves precious silicon real estate area.

Abstract: A drain-extended metal-oxide-semiconductor transistor (40) with improved robustness in breakdown characteristics is disclosed. Field oxide isolation structures (29c) are disposed between the source region (30) and drain contact regions (32a, 32b, 32c) to break the channel region of the transistor into parallel sections. The gate electrode (35) extends over the multiple channel regions, and the underlying well (26) and thus the drift region (DFT) of the transistor extends along the full channel width. Channel stop doped regions (33) underlie the field oxide isolation structures (29c), and provide conductive paths for carriers during breakdown. Parasitic bipolar conduction, and damage due to that conduction, is therefore avoided.

Abstract: An electrostatic discharge (ESD) device for protecting an input/output terminal of a circuit, the device comprising a first transistor with an integrated silicon-controlled rectifier (SCR) coupled between the input/output (I/O) terminal of the circuit and a node and a second transistor with an integrated silicon-controlled rectifier coupled between the node and a negative terminal of a supply voltage, wherein the silicon-controlled rectifier of the first transistor triggers in response to a negative ESD voltage and the silicon-controlled rectifier of the second transistor triggers in response to a positive ESD voltage.

Abstract: Depletion drain-extended MOS transistor devices and fabrication methods for making the same are provided, in which a compensated channel region is provided with p and n type dopants to facilitate depletion operation at Vgs=0, and an adjust region is implanted in the substrate proximate the channel side end of the thick gate dielectric structure for improved breakdown voltage rating. The compensated channel region is formed by overlapping implants for an n-well and a p-well, and the adjust region is formed using a Vt adjust implant with a mask exposing the adjust region.

Abstract: A CMOS integrated circuit (15A-B-C) includes both relatively low-power (124, 126) and high-power (132, 134) CMOS transistors on the same chip. A 20V, relatively high-power PMOS device (134) includes a heavily doped N-well drain region (70). A 20V, relatively high-power NMOS device (132) includes heavily doped P-type buried layers (76, 78) underneath the source (94) and drain regions (96) and spanning the gap between the P-well gate (90F) and adjacent P-well isolation regions (46, 50).

Abstract: High side extended-drain MOS driver transistors (T2) are presented in which an extended drain (108, 156) is separated from a first buried layer (120) by a second buried layer (130), wherein an internal or external diode (148) is coupled between the first buried layer (120) and the extended drain (108, 156) to increase the breakdown voltage.

Abstract: Drain-extended MOS transistors (T1, T2) and semiconductor devices (102) are described, as well as fabrication methods (202) therefor, in which a p-buried layer (130) is formed prior to formation of epitaxial silicon (106) over a substrate (104), and a drain-extended MOS transistor (T1, T2) is formed in the epitaxial silicon layer (106). The p-buried layer (130) may be formed above an n-buried layer (120) in the substrate (104) for high-side driver transistor (T2) applications, wherein the p-buried layer (130) extends between the drain-extended MOS transistor (T2) and the n-buried layer (120) to inhibit off-state breakdown between the source (154) and drain (156).

Abstract: Drain-extended MOS transistors (T1, T2) and semiconductor devices (102) are described, as well as fabrication methods (202) therefor, in which a p-buried layer (130) is formed prior to formation of epitaxial silicon (106) over a substrate (104), and a drain-extended MOS transistor (T1, T2) is formed in the epitaxial silicon layer (106). The p-buried layer (130) may be formed above an n-buried layer (120) in the substrate (104) for high-side driver transistor (T2) applications, wherein the p-buried layer (130) extends between the drain-extended MOS transistor (T2) and the n-buried layer (120) to inhibit off-state breakdown between the source (154) and drain (156).

Abstract: A CMOS integrated circuit (15A-B-C) includes both relatively low-power (124, 126) and high-power (132, 134) CMOS transistors on the same chip. A 20V, relatively high-power PMOS device (134) includes a heavily doped N-well drain region (70). A 20V, relatively high-power NMOS device (132) includes heavily doped P-type buried layers (76, 78) underneath the source (94) and drain regions (96) and spanning the gap between the P-well gate (90F) and adjacent P-well isolation regions (46, 50).

Abstract: Extended-drain MOS transistor devices and fabrication methods are provided, in which a drift region of a first conductivity type is formed between a drain of the first conductivity type and a channel. The drift region comprises first and second portions, the first portion extending partially under a gate structure between the channel and the second portion, and the second portion extending laterally between the first portion and the drain, wherein the first portion of the drift region has a concentration of first type dopants higher than the second portion.

Abstract: The present invention provides, in one embodiment, a transistor (100). The transistor (100) comprises a doped semiconductor substrate (105) and a gate structure (110) over the semiconductor substrate (105), the gate structure (110) having a gate corner (125). The transistor (100) also includes a drain-extended well (115) surrounded by the doped semiconductor substrate (105). The drain-extended well (115) has an opposite dopant type as the doped semiconductor substrate (105). The drain-extended well (115) also has a low-doped region (145) between high-doped regions (150), wherein an edge of the low-doped region (155) is substantially coincident with a perimeter (140) defined by the gate corner (125). Other embodiments of the present invention include a method of manufacturing a transistor (200) and an integrated circuit (300).

Abstract: A transistor can be fabricated to exhibit reduced channel hot carrier effects. According to one aspect of the present invention, a method for fabricating a transistor structure includes implanting a first dopant into a lightly doped drain (LDD) region to form a shallow region therein. The first dopant penetrates the substrate to a depth that is less than the LDD junction depth. A second dopant is implanted into the substrate beyond the LDD junction depth to form a source/drain region. The implantation of the second dopant overpowers a substantial portion of the first dopant to define a floating ring in the LDD region that mitigates channel hot carrier effects.

Abstract: The present invention provides a system for efficiently producing versatile, high-precision MOS device structures in which straight regions dominate the device's behavior, providing minimum geometry devices that precisely match large devices, in an easy, efficient and cost-effective manner. The present invention provides methods and apparatus for producing double diffused semiconductor devices that minimize performance impacts of end cap regions. The present invention provides a MOS structure having a moat region (404, 516, 616), and an oxide region (414, 512, 608) overlapping the moat region. A double-diffusion region (402, 504, 618) is formed within the oxide region, having end cap regions (406, 502, 620) that are effectively deactivated utilizing geometric and implant manipulations.

Abstract: A drain-extended metal-oxide-semiconductor transistor (40) with improved robustness in breakdown characteristics is disclosed. Field oxide isolation structures (29c) are disposed between the source region (30) and drain contact regions (32a, 32b, 32c) to break the channel region of the transistor into parallel sections. The gate electrode (35) extends over the multiple channel regions, and the underlying well (26) and thus the drift region (DFT) of the transistor extends along the full channel width. Channel stop doped regions (33) underlie the field oxide isolation structures (29c), and provide conductive paths for carriers during breakdown. Parasitic bipolar conduction, and damage due to that conduction, is therefore avoided.

Abstract: Segmented transistor devices are provided, wherein contiguous individual transistor segments extend along corresponding segment axes, in which two or more of the segment axes are at a non-zero angle with respect to one another. The segmentation of the transistor provides a high overall device aspect ratio which may be easily fit into pre-existing circuit blocks or cells in a device layout, thereby facilitating device scaling.

Abstract: Depletion drain-extended MOS transistor devices and fabrication methods for making the same are provided, in which a compensated channel region is provided with p and n type dopants to facilitate depletion operation at Vgs=0, and an adjust region is implanted in the substrate proximate the channel side end of the thick gate dielectric structure for improved breakdown voltage rating. The compensated channel region is formed by overlapping implants for an n-well and a p-well, and the adjust region is formed using a Vt adjust implant with a mask exposing the adjust region.

Abstract: A transistor can be fabricated to exhibit reduced channel hot carrier effects. According to one aspect of the present invention, a method for fabricating a transistor structure includes implanting a first dopant into a lightly doped drain (LDD) region to form a shallow region therein. The first dopant penetrates the substrate to a depth that is less than the LDD junction depth. A second dopant is implanted into the substrate beyond the LDD junction depth to form a source/drain region. The implantation of the second dopant overpowers a substantial portion of the first dopant to define a floating ring in the LDD region that mitigates channel hot carrier effects.