An electronics package is disclosed. The electronics package includes a first radio frequency (RF) substrate layer, a second RF substrate layer, and a plurality of conductive layers disposed adjacent to at least one of the first RF substrate layer and the second RF substrate layer and including an inner conductive layer disposed between and adjacent to both the first RF substrate layer and the second RF substrate layer. The inner conductive layer bonds the first RF substrate layer to the second RF substrate layer. The electronics package also includes a plurality of conductive interconnects extending through the first RF substrate layer and the second RF substrate layer and electrically coupled between at least two of the plurality of conductive layers.

An electronic element mounting substrate includes a substrate including a first layer, a second layer located on a lower surface of the first layer, and a third layer located on a lower surface of the second layer, and on which an electronic element is to be mounted. The substrate has a via conductor that passes through the first layer to the third layer in a vertical direction. The substrate includes respective electrical conductor layers located between the respective layers and connected to the via conductor in a plan perspective. Each electrical conductor layer includes a land portion surrounding the via conductor, a clearance portion surrounding the land portion, and a peripheral portion surrounding the clearance portion and electrically insulated from the land portion with the clearance portion interposed between the land portion and the peripheral portion. The first land portion has, in a plan perspective, a first portion overlapping the second land portion, and the first clearance portion has, in a plan perspective, a second portion not overlapping the second clearance portion. The first peripheral portion and the second peripheral portion each have, in a vertical cross-sectional view, an end portion that becomes thinner as a distance from the via conductor increases.

A temperature rise due to thermal interference between electronic components is suppressed. Electronic components (11a, 11b) are adjacently mounted on a circuit board (12). The circuit board (12) is fixed to a base (13). A rectangular convex portion (21) is provided on the base (13). The rectangular convex portion (21) is disposed so as to be located below the electronic components (11a, 11b) when the circuit board (12) is assembled to a housing (10). The rectangular convex portion (21) includes N concave portions (21a). The concave portions (21a) are arranged on a surface (21b) facing the region between the electronic components (11a, 11b).

A semiconductor package includes a chip package disposed on a substrate, a plurality of electronic components disposed aside the chip package on the substrate and a stiffener structure disposed on the substrate. The stiffener structure includes a stiffener ring surrounding the chip package and the plurality of electronic components, a stiffener rib between the chip package and the plurality of electronic components, wherein the stiffener rib includes a first portion and a second portion on the first portion, and a width of the second portion is greater than a width of the first portion. The semiconductor package further includes a lid attached to the stiffener structure, the chip package and the plurality of electronic components. A method of forming the semiconductor package is also provided.

A semiconductor package includes a chip package disposed on a substrate, a plurality of electronic components disposed aside the chip package on the substrate and a stiffener structure disposed on the substrate. The stiffener structure includes a stiffener ring surrounding the chip package and the plurality of electronic components, a stiffener rib between the chip package and the plurality of electronic components, wherein the stiffener rib includes a first portion and a second portion on the first portion, and a width of the second portion is greater than a width of the first portion. The semiconductor package further includes a lid attached to the stiffener structure, the chip package and the plurality of electronic components. A method of forming the semiconductor package is also provided.

A carrier configured to be attached to a semiconductor substrate via a first surface comprises a continuous carbon structure defining a first surface of the carrier, and a reinforcing material constituting at least 2 vol-% of the carrier.

A semiconductor device includes: a supporting member having a wiring including a die-pad; a semiconductor element bonded to the die-pad; a wire bonded to the wiring and the semiconductor element; and a bonding layer that has a conductivity and bonds the die-pad and the semiconductor element. When viewed in a thickness direction of the semiconductor element, the die-pad includes a first region included inside a peripheral edge of the semiconductor element and a second region that is connected to the first region and extends farther then the peripheral edge of the semiconductor element. When viewed in the thickness direction, the wire is separated from the second region.

Methods and apparatus to reduce defects in interconnects between semiconductor dies and package substrates are disclosed. An apparatus includes a substrate and a semiconductor die mounted to the substrate. The apparatus further includes an array of bumps to electrically couple the die to the substrate. Each of the bumps have a corresponding base. Different ones of the bases have different widths that vary spatially across the array of bumps.

Methods and apparatus to reduce defects in interconnects between semiconductor dies and package substrates are disclosed. An apparatus includes a substrate and a semiconductor die mounted to the substrate. The apparatus further includes an array of bumps to electrically couple the die to the substrate. Each of the bumps have a corresponding base. Different ones of the bases have different widths that vary spatially across the array of bumps.

An imaging module includes an imager having an optical member on a light receiving surface, an electronic component having a front surface facing the same direction as the one to which an incidence surface of the optical member faces, a resin portion that has a first surface flush with the incidence surface of the optical member and the front surface of the electronic component, and a second surface that is a surface on a side opposite to the first surface while having the imager and the electronic component being embedded therein such that the incidence surface and the front surface are exposed to the first surface, an external connection terminal provided on the second surface, and a through wiring that extends through the resin portion to connect at least one of the imager and the electronic component with the external connection terminal.