For a pressure-sensor assembly, including a carrier substrate having conductor tracks disposed on a first side of the carrier substrate, a pressure-sensor element that is mounted on the first side of the carrier substrate and is electrically contacted via a bonding-wire connection to a conductor track located on the first side of the carrier substrate, as well as a frame part having a full-perimeter frame wall, the frame part being positioned on the first side of the carrier substrate around the pressure-sensor element, and the frame part being filled with a gel covering the pressure-sensor element, it is provided that in addition to the full-perimeter frame wall, the frame part has a base which is positioned on at least one conductor track disposed on the first side of the carrier substrate.

A semiconductor package may include a package substrate, a support structure on the package substrate and having a cavity therein, and at least one first semiconductor chip on the package substrate in the cavity. The support structure may have a first inner sidewall facing the cavity, a first top surface, and a first inclined surface connecting the first inner sidewall and the first top surface. The first inclined surface may be inclined with respect to a top surface of the at least one first semiconductor chip.

A semiconductor device includes a circuit substrate, a semiconductor package, and a metallic cover. The semiconductor package is disposed on the circuit substrate. The metallic cover is disposed over the semiconductor package and over the circuit substrate. The metallic cover comprises a lid and outer flanges. The lid overlies the semiconductor package. The outer flanges are disposed at edges of the lid, are connected with the lid, extend from the lid towards the circuit substrate, and face side surfaces of the semiconductor package. The lid has a first region that is located over the semiconductor package and is thicker than a second region that is located outside a footprint of the semiconductor package.

A semiconductor device includes: an insulating substrate; a first semiconductor element connected to the insulating substrate; a conductive member disposed on the insulating substrate, and including a first opposing portion and a second opposing portion located opposite each other with respect to the first semiconductor element in plan view; a first wire connected to the first semiconductor element and the first opposing portion; and a second wire connected to the first semiconductor element and the second opposing portion, and located opposite the first wire with respect to a connection point where the first wire and the first semiconductor element are connected to each other in plan view.

Structures and formation methods of chip packages are provided. The method includes disposing a semiconductor die over a carrier substrate. The method also includes disposing an interposer substrate over the carrier substrate. The interposer substrate has a recess that penetrates through opposite surfaces of the interposer substrate. The interposer substrate has interior sidewalls surrounding the semiconductor die, and the semiconductor die is as high as or higher than the interposer substrate. The method further includes forming a protective layer in the recess of the interposer substrate to surround the semiconductor die. In addition, the method includes removing the carrier substrate and stacking a package structure over the interposer substrate.

A semiconductor device according to the present invention includes a substrate, a resin case, and a wiring member having an exposed portion adjacent to a first fixing portion fixed in a wall surface of the resin case and exposed to outside, and a second fixing portion fixed in the wall surface of the resin case at a position different from the first fixing portion with respect to a portion extending from the first fixing portion into the resin case, in which the wiring member is bonded to a surface of the semiconductor element by solder in the resin case, and has a plate shape having a length, a thickness, and a width, in which the wiring member has the thickness being uniform and is flat in the resin case, and the width of the second fixing portion is narrower than the width of the exposed portion.

A semiconductor device according to the present invention includes a substrate, a resin case, and a wiring member having an exposed portion adjacent to a first fixing portion fixed in a wall surface of the resin case and exposed to outside, and a second fixing portion fixed in the wall surface of the resin case at a position different from the first fixing portion with respect to a portion extending from the first fixing portion into the resin case, in which the wiring member is bonded to a surface of the semiconductor element by solder in the resin case, and has a plate shape having a length, a thickness, and a width, in which the wiring member has the thickness being uniform and is flat in the resin case, and the width of the second fixing portion is narrower than the width of the exposed portion.

A photoelectric conversion unit that outputs an image signal according to received light and a bonding pad section are disposed on one surface side of the substrate, and the bonding pad section has at least: a first opening provided to expose a pad electrode at a bottom; and a second opening that is arranged to surround the first opening and that is shallower than the first opening. The surface of a terrace in the bonding pad section is formed such that multiple types of materials are exposed.

Provided is a power semiconductor module that can secure insulating properties. A semiconductor element is mounted on a resin-insulated base plate including a circuit pattern, a resin insulating layer, and a base plate. A case enclosing the resin-insulated base plate is bonded to the resin insulating layer with an adhesive. The resin insulating layer and the case are bonded together with a region enclosed by the resin insulating layer and a tapered portion of the case formed closer to the resin insulating layer being filled with the adhesive made of a material identical to that of the sealing resin. Air bubbles in the adhesive appear in the tapered portion opposite to the resin insulating layer.

A photoelectric conversion unit that outputs an image signal according to received light and a bonding pad section are disposed on one surface side of the substrate, and the bonding pad section has at least: a first opening provided to expose a pad electrode at a bottom; and a second opening that is arranged to surround the first opening and that is shallower than the first opening. The surface of a terrace in the bonding pad section is formed such that multiple types of materials are exposed.