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: 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: Disclosed are devices and associated methods for manufacturing an EEPROM memory cell (10) for use on a negatively biased substrate (12). The invention may be practiced using standard semiconductor processing techniques. Devices and methods are disclosed for a floating gate transistor for use as an EEPROM cell (10) including a DNwell (14) formed on a P-type substrate (12) for isolating the EEPROM cell (10) from the underlying P-type substrate (12).

Abstract: Semiconductor devices and manufacturing methods therefor are disclosed, in which a drain-extended MOS transistor comprises a self-aligned floating region proximate one end of the transistor gate and doped with a first type dopant to reduce channel hot carrier degradation, as well as an oppositely doped first source/drain laterally spaced from the first end of the gate structure in a semiconductor body. The device may further comprise a resurf region doped to a lower concentration than the floating region to facilitate improved breakdown voltage performance. A method of fabricating a drain-extended MOS transistor in a semiconductor device is disclosed, comprising providing first dopants to a floating region in a semiconductor body, which is self-aligned with the first end of a gate structure, and providing second dopants to source/drains of the semiconductor body, wherein the first and second dopants are different.

Abstract: Disclosed are devices and associated methods for manufacturing an EEPROM memory cell (10) for use on a negatively biased substrate (12). The invention may be practiced using standard semiconductor processing techniques. Devices and methods are disclosed for a floating gate transistor for use as an EEPROM cell (10) including a DNwell (14) formed on a P-type substrate (12) for isolating the EEPROM cell (10) from the underlying P-type substrate (12).

Abstract: The concept of the present invention describes a semiconductor device with a junction 504 between a lightly doped region 501 and a heavily doped region 502, wherein the junction has an elongated portion 504a and curved portions 504b. The doping concentration of the lightly doped region is configured so that it exhibits higher resistivity in the proximity 510 of the curved portion by an amount suitable to lower the electric field strength during device operation and thus to offset the increased field strength caused by the curved portion. As a consequence, the device breakdown voltage in the curved junction portion becomes equal to or greater than the breakdown voltage in the linear portion.

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: An embodiment of the instant invention is a transistor formed on a semiconductor substrate of a first conductivity type and having an upper surface, the transistor comprising: a well region (well 204 of FIG. 1a) formed in the semiconductor substrate (layer 202 of FIG. 1a), the well region of a second conductivity type opposite that of the first conductivity type; a source region (source region 208 of FIG. 1a) formed in the well region in the semiconductor substrate, the source region of the second conductivity type; a drain region (drain 210 of FIG. 1a) formed in the semiconductor substrate and spaced away from the source region by a channel region (given by length L1+L2), the drain region of the second conductivity type; a conductive gate electrode (layer 218 of FIG. 1a) disposed over the semiconductor substrate and over the channel region; a gate insulating layer (layer 214 of FIG.

Abstract: An LDMOS device (10, 20, 50, 60) that is made with minimal feature size fabrication methods, but overcomes potential problems of misaligned Dwells (13). The Dwell (13) is slightly overstated so that its n-type dopant is implanted past the source edge of the gate region (18), which permits the n-type region of the Dwell to diffuse under the gate region (18) an sufficient distance to eliminate misalignment effects.

Abstract: An integrated circuit (IC) chip, mounted on a leadframe, has a network of power distribution lines deposited on the surface of the chip so that these lines are located over active components of the IC, connected vertically by metal-filled vias to selected active components below the lines, and also by conductors to segments of the leadframe. Furthermore, the lines are fabricated with a sheet resistance of less than 1.5 m&OHgr;/and the majority of the lines is patterned as straight lines between the vias and the conductors, respectively.

Abstract: An embodiment of the instant invention is a transistor formed on a semiconductor substrate of a first conductivity type and having an upper surface, the transistor comprising: a well region (well 204 of FIG. 1a) formed in the semiconductor substrate (layer 202 of FIG. 1a), the well region of a second conductivity type opposite that of the first conductivity type; a source region (source region 208 of FIG. 1a) formed in the well region in the semiconductor substrate, the source region of the second conductivity type; a drain region (drain 210 of FIG. 1a) formed in the semiconductor substrate and spaced away from the source region by a channel region (given by length L1+L2), the drain region of the second conductivity type; a conductive gate electrode (layer 218 of FIG. 1a) disposed over the semiconductor substrate and over the channel region; a gate insulating layer (layer 214 of FIG.

Abstract: A method of minimizing parasitics in an MOS device caused by the formation of a bipolar transistor within the MOS devices and the device, primarily for a polyphase bridge circuit. For the low side device, a substrate of a first conductivity type is provided having a first buried layer of opposite conductivity type thereon. A second buried layer of the first conductivity type is formed over the first buried layer and a further layer of the first conductivity type is formed over the second buried layer. A sinker extending through the further layer to the first buried layer is formed to isolate the second buried layer and the further layer from the substrate. Formation of an MOS device in the further layer including source, drain and gate regions is completed and the sinker is connected to a source terminal of the device.

Abstract: A method of minimizing parasitics in an MOS device caused by the formation of a bipolar transistor within the MOS devices and the device, primarily for a polyphase bridge circuit. For the low side device, a substrate of a first conductivity type is provided having a first buried layer of opposite conductivity type thereon. A second buried layer of the first conductivity type is formed over the first buried layer and a further layer of the first conductivity type is formed over the second buried layer. A sinker extending through the further layer to the first buried layer is formed to isolate the second buried layer and the further layer from the substrate. Formation of an MOS device in the further layer including source, drain and gate regions is completed and the sinker is connected to a source terminal of the device.

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.

Abstract: A RESURF LDMOS transistor (32) has a drain region including a first region (24) and a deep drain buffer region (34) surrounding the first region. The first region is more heavily doped than the deep drain buffer region. The deep drain buffer region improves the robustness of the transistor.