An electronic device includes a package substrate, at least one integrated circuit (IC) die including a substrate having a semiconductor surface including circuitry electrically coupled to bond pads positioned onto contact pads on a top surface of a package substrate. At least one surface mount device (SMD) component including at least a first terminal and a second terminal is on the package substrate positioned lateral to the IC die. There is at least one SMD interconnect electrically connecting to at least one of the first terminal and the second terminal to the bond pads. The SMD interconnect includes a portion of a tie bar that extends to an outer edge of the electronic device.

A semiconductor package structure and a method for manufacturing a semiconductor package structure are provided. The semiconductor package structure includes a semiconductor package device, a first constraint structure and a second constraint structure. The first constraint structure is connected to the semiconductor package device. The second constraint structure is connected to the semiconductor package device and under a projection of the semiconductor package device.

A circuit board, on which a packaged semiconductor integrated circuit is to be mounted, includes a substrate, a heat-dissipating connection pad, and a first open area. The substrate includes a substrate body having a main surface, a metal layer located on the main surface, and an insulating layer located on the metal layer. In the heat-dissipating connection pad, the metal layer is exposed from an opening in the insulating layer. The heat-dissipating connection pad is connectable to a heat-dissipating unit of the semiconductor integrated circuit via a bond. In the first open area, the metal layer is exposed from an opening in the insulating layer located outboard with respect to a periphery of the heat-dissipating connection pad.

A substrate structure including a carrier and a substrate is provided. The carrier includes a release layer, a dielectric layer and a metal layer. The dielectric layer is disposed between the release layer and the metal layer. The substrate includes a packaging region and a peripheral region. The peripheral region is connected to the packaging region and surrounds the packaging region. The peripheral region or the packaging region has a plurality of through holes. The substrate is disposed on the carrier. The release layer is located between the substrate and the dielectric layer. The release layer and the dielectric layer are filled in the through hole such that the substrate is separably attached to the carrier.

An integrated circuit die is disclosed that comprises a substrate defining a plurality of circuit elements; a sensor region on the substrate, the sensor region comprising a layer stack defining a plurality of CMUT (capacitive micromachined ultrasound transducer) cells; and an interposer region on the substrate adjacent to the sensor region. The interposer region comprises a further layer stack including conductive connections to the circuit elements and the CMUT cells, the conductive connections connected to a plurality of conductive contact regions on an upper surface of the interposer region, the conductive contact regions including external contacts for contacting the integrated circuit die to a connection cable and mounting pads for mounting a passive component on the upper surface. A probe including such an integrated circuit die an ultrasound system including such a probe are also disclosed.

The present disclosure describes light systems in which the intensity of base color LEDs configured to emit light within a target color region is increased using additional white LEDs and the emitted light is filtered so that a dominant portion of light passing through the filter at a particular viewing angle is within the target color region. The present disclosure also describes methods for forming a printed circuit board with an integral heat sink arrangement by depositing additional solder on solder pads that are not used to connect electronic components so that the additional solder acts as a heat sink.

A method and apparatus to electronically sense air flow and close a switch when air flow is adequate to operate an electric heater, HVACR system, or other apparatus. The apparatus is more reliable than electro-mechanical devices often used for this purpose.

An electronic device package includes a molded case, a plurality of leads and a case lid. The molded case includes integrally formed side walls, end walls, and a bottom wall, which together define an interior for components. Each side wall includes top and bottom portions. The top portion includes first and second surfaces extending downward from a top edge of the side wall. The bottom portion has a top surface that extends away from the interior, a third surface extending downward from the top surface to a bottom edge, and a fourth surface extending downward from the second surface to the bottom wall. The leads are molded in the side wall from the bottom edge to the top edge. Each lead has an end extending above the top edge, and another end extending along the bottom edge of the side wall. The case lid is engaged with the molded case.

In one embodiment, an electronic system includes a printed circuit board, one or more packaged semiconductor devices, and a vapor chamber having a top and a bottom and enclosing a sealed cavity that is partially filled with a coolant. The vapor chamber comprises a thermo-conductive and electro-conductive material. The top of the vapor chamber has one or more depressions formed therein, each depression receiving and thermo-conductively connected to at least part of a bottom of a corresponding packaged semiconductor device, which is mounted through a corresponding aperture in the PCB. A heat sink may be thermo-conductively attached to the bottom of the vapor chamber.

A retention structure which provides both soldering and vibration stabilization of a capacitor as the capacitor is mounted to a printed circuit board (PCB) of an electronic module. An aperture is part of the PCB to stabilize and prevent the capacitor from rolling during manufacturing. Once secured to the PCB, Room Temperature Vulcanization (RTV), or similar adhesive bead, is placed onto a rigidizer or base plate (typically a casted or aluminum sheet plate). Once the capacitor is soldered in place and fixated on the PCB, the assembly is then placed onto the rigidizer such that the PCB is attached to the rigidizer using an adhesive, and the RTV bead contacts and is deformed by the capacitor, connecting the capacitor to the rigidizer to provide vibration stabilization support. The electronic module includes a cover, and optional dampening/constraint pads are attached to the cover of the electrolytic capacitor for additional vibration stabilization.