Abstract: An integrated circuit and method having an extended drain MOS transistor with a buried drift region, a drain diffused link, a channel diffused link, and an isolation link which electrically isolated the source, where the isolation diffused link is formed by implanting through segmented areas to dilute the doping to less than two-thirds the doping in the drain diffused link.

Abstract: A semiconductor device containing a high voltage MOS transistor with a drain drift region over a lower drain layer and channel regions laterally disposed at the top surface of the substrate. RESURF trenches cut through the drain drift region and body region parallel to channel current flow. The RESURF trenches have dielectric liners and electrically conductive RESURF elements on the liners. Source contact metal is disposed over the body region and source regions. A semiconductor device containing a high voltage MOS transistor with a drain drift region over a lower drain layer, and channel regions laterally disposed at the top surface of the substrate. RESURF trenches cut through the drain drift region and body region perpendicular to channel current flow. Source contact metal is disposed in a source contact trench and extended over the drain drift region to provide a field plate.

Abstract: An integrated circuit including a high-voltage n-channel MOS power transistor, a high-voltage n-channel MOS blocking transistor, a high-voltage n-channel MOS reference transistor, and a voltage comparator, configured to provide an overcurrent signal if drain current through the power transistor in the on state exceeds a predetermined value. The power transistor source node is grounded. The blocking transistor drain node is connected to the power transistor drain node. The blocking transistor source node is coupled to the comparator non-inverting input. The reference transistor drain node is fed by a current source and is connected to the comparator inverting input. The reference transistor gate node is coupled to a gate node of the power transistor. The comparator output provides the overcurrent signal. A process of operating the integrated circuit is disclosed.

Abstract: A semiconductor device has a vertical drain extended MOS transistor with deep trench structures to define a vertical drift region and at least one vertical drain contact region, separated from the vertical drift region by at least one instance of the deep trench structures. Dopants are implanted into the vertical drain contact regions and the semiconductor device is annealed so that the implanted dopants diffuse proximate to a bottom of the deep trench structures. The vertical drain contact regions make electrical contact to the proximate vertical drift region at the bottom of the intervening deep trench structure. At least one gate, body region and source region are formed above the drift region at, or proximate to, a top surface of a substrate of the semiconductor device. The deep trench structures are spaced so as to form RESURF regions for the drift region.

Abstract: A semiconductor device having a vertical drain extended MOS transistor may be formed by forming deep trench structures to define vertical drift regions of the transistor, so that each vertical drift region is bounded on at least two opposite sides by the deep trench structures. The deep trench structures are spaced so as to form RESURF regions for the drift region. Trench gates are formed in trenches in the substrate over the vertical drift regions. The body regions are located in the substrate over the vertical drift regions.

Abstract: A semiconductor device having a vertical drain extended MOS transistor may be formed by forming deep trench structures to define at least one vertical drift region bounded on at least two opposite sides by the deep trench structures. The deep trench structures include dielectric liners. The deep trench structures are spaced so as to form RESURF regions for the drift region. Vertical gates are formed in vertically oriented gate trenches in the dielectric liners of the deep trench structures, abutting the vertical drift regions. A body implant mask for implanting dopants for the transistor body is also used as an etch mask for forming the vertically oriented gate trenches in the dielectric liners.

Abstract: A semiconductor device containing a high voltage MOS transistor with a drain drift region over a lower drain layer and channel regions laterally disposed at the top surface of the substrate. RESURF trenches cut through the drain drift region and body region parallel to channel current flow. The RESURF trenches have dielectric liners and electrically conductive RESURF elements on the liners. Source contact metal is disposed over the body region and source regions. A semiconductor device containing a high voltage MOS transistor with a drain drift region over a lower drain layer, and channel regions laterally disposed at the top surface of the substrate. RESURF trenches cut through the drain drift region and body region perpendicular to channel current flow. Source contact metal is disposed in a source contact trench and extended over the drain drift region to provide a field plate.

Abstract: An apparatus includes an interior component, movably attached to an exterior component. Rotation of the exterior component causes an actuation piece to activate a circuit provided to either the interior or exterior component. Activation of the circuit causes sound to be played from a speaker provided to either the interior or exterior component. Also included is a hollow portion provided to the interior component, of sufficient diameter to fit a bottle top therein. Also, the apparatus includes a grip, provided on the hollow portion and operable to fixedly engage the bottle top at least when the exterior component is rotated. Rotation of the exterior component relative to the interior component causes engagement of the interior component by the exterior component, such that the interior component is caused to rotate in concert with the exterior component, further causing rotation of the bottle top which the grip fixedly engages.

Abstract: An integrated circuit including a high-voltage n-channel MOS power transistor, a high-voltage n-channel MOS blocking transistor, a high-voltage n-channel MOS reference transistor, and a voltage comparator, configured to provide an overcurrent signal if drain current through the power transistor in the on state exceeds a predetermined value. The power transistor source node is grounded. The blocking transistor drain node is connected to the power transistor drain node. The blocking transistor source node is coupled to the comparator non-inverting input. The reference transistor drain node is fed by a current source and is connected to the comparator inverting input. The reference transistor gate node is coupled to a gate node of the power transistor. The comparator output provides the overcurrent signal. A process of operating the integrated circuit is disclosed.

Abstract: Fashioning a quasi-vertical gated NPN-PNP (QVGNP) electrostatic discharge (ESD) protection device is disclosed. The QVGNP ESD protection device has a well having one conductivity type formed adjacent to a deep well having another conductivity type. The device has a desired holding voltage and a substantially homogenous current flow, and is thus highly robust. The device can be fashioned in a cost effective manner by being formed during a BiCMOS or Smart Power fabrication process.

Abstract: An integrated circuit containing a voltage divider having an upper resistor of unsilicided gate material over field oxide around a central opening and a drift layer under the upper resistor, an input terminal coupled to an input node of the upper resistor adjacent to the central opening in the field oxide and coupled to the drift layer through the central opening, a sense terminal coupled to a sense node on the upper resistor opposite from the input node, a lower resistor with a sense node coupled to the sense terminal and a reference node, and a reference terminal coupled to the reference node. A process of forming the integrated circuit containing the voltage divider.

Abstract: An integrated circuit containing a gate controlled voltage divider having an upper resistor on field oxide in series with a transistor switch in series with a lower resistor. A resistor drift layer is disposed under the upper resistor, and the transistor switch includes a switch drift layer adjacent to the resistor drift layer, separated by a region which prevents breakdown between the drift layers. The switch drift layer provides an extended drain or collector for the transistor switch. A sense terminal of the voltage divider is coupled to a source or emitter node of the transistor and to the lower resistor. An input terminal is coupled to the upper resistor and the resistor drift layer. A process of forming the integrated circuit containing the gate controlled voltage divider.

Abstract: Integrated circuits (ICs) utilize bipolar transistors in electro-static discharge (ESD) protection circuits to shunt discharge currents during ESD events to protect the components in the ICs. Bipolar transistors are subject to non-uniform current crowding across the emitter-base junction during ESD events, which results in less protection for the IC components and degradation of the bipolar transistor. This invention comprises multiple contact islands (126) on the emitter (116) of a bipolar transistor, which act to spread current uniformly across the emitter-base junction. Also included in this invention is segmentation of the emitter diffused region to further improve current uniformity and biasing of the transistor. This invention can be combined with drift region ballasting or back-end ballasting to optimize an ESD protection circuit.

Abstract: A packaged multi-output converter (200) comprising a leadframe with a chip pad (201) as ground terminal and a plurality of leads (202) including the electrical input terminal (203); a first FET chip (sync chip, 220) with its source terminal affixed to the leadframe and on its opposite surface a first drain terminal (221) positioned adjacent to a second drain terminal (222), the drain terminals connected respectively by a first (241) and a second (242) metal clip to a first (204) and second (205) output lead; a second FET chip (control chip, 211), positioned vertically over the first drain terminal, with its source terminal attached onto the first clip; a third FET chip (control chip, 212), positioned vertically over the second drain terminal, with its source terminal attached onto the second clip; and the drain terminals (213, 214) of the second and third chips attached onto a third metal clip (260) connected to the input lead (203).

Abstract: An electronic device has a plurality of trenches formed in a semiconductor layer. A vertical drift region is located between and adjacent the trenches. An electrode is located within each trench, the electrode having a gate electrode section and a field plate section. A graded field plate dielectric having increased thickness at greater depth is located between the field plate section and the vertical drift region.

Abstract: A semiconductor device containing a high voltage MOS transistor with a drain drift region over a lower drain layer and channel regions laterally disposed at the top surface of the substrate. RESURF trenches cut through the drain drift region and body region parallel to channel current flow. The RESURF trenches have dielectric liners and electrically conductive RESURF elements on the liners. Source contact metal is disposed over the body region and source regions. A semiconductor device containing a high voltage MOS transistor with a drain drift region over a lower drain layer, and channel regions laterally disposed at the top surface of the substrate. RESURF trenches cut through the drain drift region and body region perpendicular to channel current flow. Source contact metal is disposed in a source contact trench and extended over the drain drift region to provide a field plate.

Abstract: An integrated circuit containing an extended drain MOS transistor with deep semiconductor (SC) RESURF trenches in the drift region, in which each deep SC RESURF trench has a semiconductor RESURF layer at a sidewall of the trench contacting the drift region. The semiconductor RESURF layer has an opposite conductivity type from the drift region. The deep SC RESURF trenches have depth:width ratios of at least 5:1, and do not extend through a bottom surface of the drift region. A process of forming an integrated circuit with deep SC RESURF trenches in the drift region by etching undersized trenches and counterdoping the sidewall region to form the semiconductor RESURF layer. A process of forming an integrated circuit with deep SC RESURF trenches in the drift region by etching trenches and growing an epitaxial layer on the sidewall region to form the semiconductor RESURF layer.

Abstract: An integrated circuit on a (100) substrate containing an n-channel extended drain MOS transistor with drift region current flow oriented in the <100> direction with stressor RESURF trenches in the drift region. The stressor RESURF trenches have stressor elements with more than 100 MPa compressive stress. An integrated circuit on a (100) substrate containing an n-channel extended drain MOS transistor with drift region current flow oriented in the <110> direction with stressor RESURF trenches in the drift region. The stressor RESURF trenches have stressor elements with more than 100 MPa compressive stress. An integrated circuit on a (100) substrate containing a p-channel extended drain MOS transistor with drift region current flow oriented in a <110> direction with stressor RESURF trenches in the drift region. The stressor RESURF trenches have stressor elements with more than 100 MPa tensile stress.

Abstract: An integrated circuit containing a stacked bipolar transistor which includes two bipolar transistors connected in series is disclosed. Each bipolar transistor includes a breakdown inducing feature. The breakdown inducing features have reflection symmetry with respect to each other. A process for forming an integrated circuit containing a stacked bipolar transistor which includes two bipolar transistors connected in series, with breakdown inducing features having reflection symmetry, is also disclosed.

Abstract: A planar integrated MEMS device has a piezoelectric element on a dielectric isolation layer over a flexible element attached to a proof mass. The piezoelectric element contains a ferroelectric element with a perovskite structure formed over an isolation dielectric. At least two electrodes are formed on the ferroelectric element. An upper hydrogen barrier is formed over the piezoelectric element. Front side singulation trenches are formed at a periphery of the MEMS device extending into the semiconductor substrate. A DRIE process removes material from the bottom side of the substrate to form the flexible element, removes material from the substrate under the front side singulation trenches, and forms the proof mass from substrate material. The piezoelectric element overlaps the flexible element.