Abstract: An apparatus for guidance and retention of integrated circuit boards includes a first structure configured to receive a first integrated circuit board and guide the first integrated circuit board for coupling to a substrate. The apparatus further includes a second structure configured to be removably coupled to the first structure. The second structure includes a first spring member configured to apply a first compressive force to the first integrated circuit board.

Abstract: An electronic device may be provided with optical markers. A marker may be formed from a coating. The coating may be patterned to form a two-dimensional optical code or may be patterned to form an outline or other recognizable marker structure that helps provide information about an electronic device. A device with a sensor such as a depth sensor or other sensor may gather information on the electronic device and its markers. This information may include information on images captured with an image sensor while the electronic device is illuminated by one or more light beams from the depth sensor or other light sources. Markers may be configured to serve as mixed reality optical markers in a mixed reality system. Analysis of the mixed reality marker images or other sensor data may reveal information on device type, device location, device size, device orientation, and other information on a marked device.

Abstract: An optical sensing device includes a planar substrate and an array of optical transceivers disposed on the planar substrate. Each optical transceiver includes a photodetector, at least one turning mirror having a reflective surface disposed diagonally relative to the substrate, and multiple waveguides disposed parallel to the substrate. The waveguides include a transmit waveguide, which is coupled to convey outgoing light from a coherent light source to the at least one turning mirror for output from the optical transceiver, and a receive waveguide, which is coupled to receive incoming light reflected by the at least one turning mirror and to convey the incoming light to the photodetector.

Abstract: Compact trench-gate semiconductor devices, for example a cellular power MOSFET with sub-micron pitch (Yc), are manufactured with self-aligned techniques that use sidewall spacers (52) in different ways. Thereby, the source region (13) and a contact window (18a) for a source electrode (33) can be self-aligned to a narrow trench (20) containing the trench-gate (11). Thereby, the channel-accommodating region (15) can also be provided after forming the trench-gate (11), and with very good control of its doping concentration (Na; p) adjacent to the trench (20). To achieve this control, its dopant is provided after removing the spacers (52) from the mask (51) so as to form a doping window (51b), which may also be used for the source dopant, adjacent to the trench-gate (11). A high energy dopant implant (61) or other doping process provides this channel dopant adjacent to the trench (20) and extending laterally below the mask (51,51n).

Abstract: Compact trench-gate semiconductor devices, for example a cellular power MOSFET with sub-micron pitch (Yc), are manufactured with self-aligned techniques that use sidewall spacers (52) in different ways. The trench-gate (11) is accommodated in a narrow trench (20) that is etched via a narrow window (52b) defined by the spacers (52) at sidewalls of a wider window (51a) of a mask (51) at the body surface (10a). The spacers (52) permit a source region (13) adjacent to the trench-gate (11) and an insulating overlayer (18) over the trench-gate (11) to be self-aligned to this narrow trench (20). The overlayer (18), which defines a contact window (18a) for a source electrode (33), is provided in a simple but reproducible manner by deposition and etch-back, after removing the spacers (52). Its overlap (y4, y4′) with the body surface (10a) is well-defined, so reducing a short-circuit risk between the source electrode (33) and the trench-gate (11).

Abstract: Compact trench-gate semiconductor devices, for example a cellular power MOSFET with sub-micron pitch (Yc), are manufactured with self-aligned techniques that use sidewall spacers (52) in different ways. The trench-gate (11) is accommodated in a narrow trench (20) that is etched via a narrow window (52b) defined by the spacers (52) at sidewalls of a wider window (51a) of a mask (51) at the body surface (10a). The spacers (52) permit a source region (13) adjacent to the trench-gate (11) and an insulating overlayer (18) over the trench-gate (11) to be self-aligned to this narrow trench (20). The overlayer (18), which defines a contact window (18a) for a source electrode (33), is provided in a simple but reproducible manner by deposition and etch-back, after removing the spacers (52). Its overlap (y4, y4′) with the body surface (10a) is well-defined, so reducing a short-circuit risk between the source electrode (33) and the trench-gate (11).

Abstract: Compact trench-gate semiconductor devices, for example a cellular power MOSFET with sub-micron pitch (Yc), are manufactured with self-aligned techniques that use sidewall spacers (52) in different ways. Thereby, the source region (13) and a contact window (18a) for a source electrode (33) can be self-aligned to a narrow trench (20) containing the trench-gate (11). Thereby, the channel-accommodating region (15) can also be provided after forming the trench-gate (11), and with very good control of its doping concentration (Na; p) adjacent to the trench (20). To achieve this control, its dopant is provided after removing the spacers (52) from the mask (51) so as to form a doping window (51b), which may also be used for the source dopant, adjacent to the trench-gate (11). A high energy dopant implant (61) or other doping process provides this channel dopant adjacent to the trench (20) and extending laterally below the mask (51, 51n).