Abstract: An instrumentation amplifier includes first and second resistors for gain setting. The operational amplifiers within the instrumentation amplifier include selectively enabled current drive sources coupled to the amplifier output. The first and second resistors have variable resistances. A control circuit is configured to select the variable resistances of the first and second resistors to implement a fixed gain for the instrumentation amplifier and further selectively enable the current drive sources. The control circuit receives an indication of a downstream programmable gain (for example, from a downstream programmable gain amplifier). The variable resistances of the first and second resistors are selected to be scaled inversely with respect to the downstream programmable gain and the current drive sources are enabled proportionately with respect to the downstream programmable gain.

Abstract: An integrated circuit transistor is formed on and in a substrate. A trench in the substrate is at least partially filed with a metal material to form a source (or drain) contact buried in the substrate. The substrate further includes a source (or drain) region epitaxially grown above the source (or drain) contact. The substrate further includes a channel region adjacent to the source (or drain) region. A gate dielectric is provided on top of the channel region and a gate electrode is provided on top of the gate dielectric. The substrate is preferably of the silicon on insulator (SOI) type.

Abstract: An ashing chemistry employing a combination of Cl2 and N2 is provided, which removes residual material from sidewalls of a patterned metallic hard mask layer without residue such that the sidewalls of the patterned metallic hard mask layer are vertical. The vertical profiled of the sidewalls of the patterned metallic hard mask layer can be advantageously employed to reduce pattern factor dependency in the etch bias between the pattern transferred into an underlying layer and the pattern as formed on the metallic hard mask layer. Further, the ashing chemistry can be employed to enhance removal of stringers in vertical portions of a metallic material layer.

Abstract: A strip of sacrificial semiconductor material is formed on top of a non-sacrificial semiconductor material substrate layer. A conformal layer of the non-sacrificial semiconductor material is epitaxially grown to cover the substrate layer and the strip of sacrificial semiconductor material. An etch is performed to selectively remove the strip of sacrificial semiconductor material and leave a hollow channel surrounded by the conformal layer and the substrate layer. Using an anneal, the conformal layer and the substrate layer are reflowed to produce an optical waveguide structure including the hollow channel.

Abstract: An integrated circuit transistor is formed on and in a substrate. A trench in the substrate is at least partially filed with a metal material to form a source (or drain) contact buried in the substrate. The substrate further includes a source (or drain) region epitaxially grown above the source (or drain) contact. The substrate further includes a channel region adjacent to the source (or drain) region. A gate dielectric is provided on top of the channel region and a gate electrode is provided on top of the gate dielectric. The substrate is preferably of the silicon on insulator (SOI) type.

Abstract: A semiconductor material is patterned to define elongated fins insulated from an underlying substrate. A polysilicon semiconductor material is deposited over and in between the elongated fins, and is patterned to define elongated gates extending to perpendicularly cross over the elongated fins at a transistor channel. Sidewall spacers are formed on side walls of the elongated gates. Portions of the elongated fins located between the elongated gates are removed, along with the underlying insulation, to expose the underlying substrate. One or more semiconductor material layers are then epitaxially grown from the underlying substrate at locations between the elongated gates. The one or more semiconductor material layers may include an undoped epi-layer and an overlying doped epi-layer. The epitaxial material defines a source or drain of the transistor.

Abstract: Delamination of stacked integrated circuit die configurations on printed circuit boards is avoided by providing a metal trace support structure underneath the die stack. The metal trace support structure features substantially equally spaced thin metal traces in place of a contiguous metal plate which has been used in the past. Spaced apart thin metal traces are less vulnerable to thermal expansion than a metal plate which has a large thermal mass. The metal traces still provide structural stability, while preventing delamination of the die stack configuration during thermal processing. A method of attaching a bridge die stack configuration to a printed circuit board by adhering a die attach film to a field of metal traces is demonstrated. In addition, the electrical and structural integrity of the bridge die stack formed with a metal trace support structure is confirmed with test results.

Abstract: A semiconductor device may include an IC, and lead frame contact areas adjacent the IC. Each lead frame contact area may have a lead opening. The semiconductor device may include bond wires, each bond wire coupling a respective lead frame contact area with the IC. The semiconductor device may include encapsulation material surrounding the IC, the lead frame contact areas, and the bond wires, and leads. Each lead may extend through a respective lead opening and outwardly from the encapsulation material.

Abstract: A method for making a semiconductor device may include bonding a top lead frame component, having recesses, with a bottom lead frame component to form a lead frame, the top and bottom lead frame components each including metal. The method may include mounting an IC on the lead frame, encapsulating the IC and the lead frame, and removing portions of the bottom lead frame component to define contacts for the IC.

Abstract: A method for making a semiconductor device includes forming laterally spaced-apart semiconductor fins above a substrate. At least one dielectric layer is formed adjacent an end portion of the semiconductor fins and within the space between adjacent semiconductor fins. A pair of sidewall spacers is formed adjacent outermost semiconductor fins at the end portion of the semiconductor fins. The at least one dielectric layer and end portion of the semiconductor fins between the pair of sidewall spacers are removed. Source/drain regions are formed between the pair of sidewall spacers.

Abstract: A device and method are provided for detecting a root moisture content of clothing in a clothes dryer. The dryer has two conducting bars situated in the dryer bin. A pulse generator circuit is coupled to the conducting bars. A microcontroller is coupled to an output of the pulse generator circuit. The pulse generator circuit generates a pulse when wet clothing contacts the conducting bars in the dryer bin. The microcontroller receives the pulses and counts the pulses that are longer than a threshold length. The microcontroller issues a termination signal based on the number of counted pulses.

Abstract: Methods and structures for forming short-channel finFETs with vertical and abrupt source and drain junctions are described. During fabrication, source and drain regions of the finFET may be recessed vertically and laterally under gate spacers. A buffer having a high dopant density may be formed on vertical sidewalls of the channel region after recessing the fin. Raised source and drain structures may be formed at the recessed source and drain regions. The raised source and drain structures may impart strain to the channel region.

Abstract: Techniques and structures for shaping the source and drain junction profiles of a finFET are described. A fin may be partially recessed at the source and drain regions of the finFET. The partially recessed fin may be further recessed laterally and vertically, such that the laterally recessed portion extends under at least a portion of the finFET's gate structure. Source and drain regions of the finFET may be formed by growing a buffer layer on the etched surfaces of the fin and/or growing a source and drain layer at the source and drain regions of the fin. The lateral recess can improve channel-length uniformity along the height of the fin.

Abstract: An AC/DC power converter is coupled between a fluorescent ballast circuit and a set of light emitting diodes (LEDs) forming an LED lamp. The power converter converts an AC output from the ballast circuit to a DC current applied to drive operation of the LEDs. The power converter transforms and rectifies the AC output from the ballast circuit to generate a DC output current. An open load protection circuit is coupled to protect the ballast circuit when the LED lamp is not connected. Current control is provided by a transistor having a source/drain conduction path coupled to shunt the DC output current in response to a control signal having a duty cycle generated as a function of a zero-crossing of the AC output and a sensed value of the DC output current applied to the LED lamp.

Abstract: A method of producing a microelectronic device in a substrate including a first semiconductor layer, a dielectric layer and a second monocrystalline semiconductor layer, the method including: etching a trench through the first semiconductor layer and the dielectric layer, and such that the trench delimits one active region of the microelectronic device; chemical vapor etching the second semiconductor layer, at a level of a bottom wall of the trench, according to at least two crystalline planes of the second semiconductor layer such that an etched part of the second semiconductor layer extends under a part of the active region; filling the trench and the etched part of the second semiconductor layer with a dielectric material.

Abstract: A system includes a primary functionality and a backup functionality for the primary functionality. A measurement circuit measures operational parameter values of the primary functionality. A fault detection circuit determines a level of equivalence between the operation of the primary functionality and a reference functionality based on a weighted comparison of the measured operational parameter values of the primary functionality to corresponding reference operational parameter values for the reference functionality If the equivalence determination fails to find equivalence, the fault detection circuit signals a fault in the primary functionality and activates the backup functionality.

Abstract: A method for making a semiconductor device may include forming, above a substrate, first and second semiconductor regions laterally adjacent one another and each including a first semiconductor material. The first semiconductor region may have a greater vertical thickness than the second semiconductor region and define a sidewall with the second semiconductor region. The method may further include forming a spacer above the second semiconductor region and adjacent the sidewall, and forming a third semiconductor region above the second semiconductor region and adjacent the spacer, with the second semiconductor region including a second semiconductor material different than the first semiconductor material. The method may also include removing the spacer and portions of the first semiconductor material beneath the spacer, forming a first set of fins from the first semiconductor region, and forming a second set of fins from the second and third semiconductor regions.

Abstract: A method for making a semiconductor device may include forming first and second spaced apart semiconductor active regions with an insulating region therebetween, forming at least one sacrificial gate line extending between the first and second spaced apart semiconductor active regions and over the insulating region, and forming sidewall spacers on opposing sides of the at least one sacrificial gate line. The method may further include removing portions of the at least one sacrificial gate line within the sidewall spacers and above the insulating region defining at least one gate line end recess, filling the at least one gate line end recess with a dielectric material, and forming respective replacement gates in place of portions of the at least one sacrificial gate line above the first and second spaced apart semiconductor active regions.

Abstract: A method for making a semiconductor device includes forming at least one gate stack on a layer comprising a first semiconductor material and etching source and drain recesses adjacent the at least one gate stack. The method further includes shaping the source and drain recesses to have a vertical side extending upwardly from a bottom to an inclined extension adjacent the at least one gate stack.

Abstract: An access point (AP) associated with a several mobile stations (STAs) implements a slot-based power save poll (PS-Poll) method. The AP divides a slot-based access period into multiple time slots and allocates each time slot to either a STA determined to have slot-based PS-Poll capabilities or a STA determined to have buffered data present at the AP. The AP creates a traffic indication map (TIM) having a number of bits equal to the number of stations associated with the AP, and then transmits a beacon including the TIM. The TIM indicates to a slot-based PS-Poll capable STA which time slots are assigned to a selected set of associated stations. After receiving the beacon from the AP, the STA refrains from attempting to communicate with the AP outside the time slot assigned to the STA, yet transmits information to the AP during the time slot assigned to the STA.