A semiconductor device assembly includes a substrate and a die coupled to the substrate. The die includes a first contact pad electrically coupled to a first circuit on the die including at least one active circuit element, and a second contact pad electrically coupled to a second circuit on the die including only passive circuit elements. The substrate includes a substrate contact electrically coupled to both the first and second contact pads. The semiconductor device assembly can further include a second die including a third contact pad electrically coupled to a third circuit on the second die including at least a second active circuit element, and a fourth contact pad electrically coupled to a fourth circuit on the second die including only passive circuit elements. The substrate contact can be electrically coupled to the third contact pad and electrically disconnected from the fourth contact pad.

A first wiring is disposed above operating regions of plural unit transistors formed on a substrate. A second wiring is disposed above the substrate. An insulating film is disposed on the first and second wirings. First and second cavities are formed in the insulating film. As viewed from above, the first and second cavities entirely overlap with the first and second wirings, respectively. A first bump is disposed on the insulating film and is electrically connected to the first wiring via the first cavity. A second bump is disposed on the insulating film and is electrically connected to the second wiring via the second cavity. As viewed from above, at least one of the plural operating regions is disposed within the first bump and is at least partially disposed outside the first cavity. The planar configuration of the first cavity and that of the second cavity are substantially identical.

A transistor includes a semiconductor region provided on a substrate and three different terminal electrodes. At least one terminal electrode has an isolated electrode structure composed of a plurality of conductor patterns. A bump, which electrically connects the plurality of conductor patterns to each other, is arranged on the terminal electrode having the isolated electrode structure. A stress-relaxing layer, which is composed of a metal material containing a high-melting-point metal, is arranged between the semiconductor region of the transistor and the bump. No current path for connecting the plurality of conductor patterns to each other is arranged between the conductor patterns and the bump.

A semiconductor device includes a heterojunction bipolar transistor and a bump. The heterojunction bipolar transistor (HBT) includes a plurality of unit transistors. The bump is electrically connected to emitters of the plurality of unit transistors through respective overlying conductor filled via openings that overlap in a plan view with a width portion of the bump. The semiconductor device reduces heat resistance in an HBT cell by satisfying two conditions, the first of which is related to specific sizing and positioning of a width portion of the overlying via opening relative to the width portion of the bump, and the second of which is related to positioning the base electrode entirely within a specific region of the width portion of the overlapping overlying via opening.

The present application discloses a method for fabricating a semiconductor device with slanted conductive layers. The method for fabricating a semiconductor device includes providing a substrate, forming a first insulating layer above the substrate, forming first slanted recesses along the first insulating layer, and forming first slanted conductive layers in the first slanted recesses and a top conductive layer covering the first slanted conductive layers.

A semiconductor device includes a first electronic component, a second electronic component and a plurality of interconnection structures. The first electronic component has a first surface. The second electronic component is over the first electronic component, and the second electronic component has a second surface facing the first surface of the first electronic component. The interconnection structures are between and electrically connected to the first electronic component and the second electronic component, wherein each of the interconnection structures has a length along a first direction substantially parallel to the first surface and the second surface, a width along a second direction substantially parallel to the first surface and the second surface and substantially perpendicular to the first direction, and the length is larger than the width of at least one of the interconnection structures.

A multi-chip module, and method of fabricating the multi-chip module. The multi-chip module includes: a substrate containing multiple wiring layers, each wiring layer having first pads on a top surface of the substrate and second pads on a bottom surface of the substrate, wherein the second pads include split pad and a conventional pad; a first solder ball in direct physical contact with a contiguous bottom surface of the conventional pad and connected to a next level of packaging under the conventional pad, wherein the first solder ball has a first height; and a second solder ball in direct physical contact with first and second sections of the split pad separated by a gap, wherein the second solder ball has a second height that is sufficiently less than the first height such that the second solder ball is not connected to the next level of packaging.

The present application discloses a double-sided SiP packaging structure and a manufacturing method thereof, wherein the double-sided SiP packaging structure comprises a substrate, a first packaging structure arranged on the substrate, and a second packaging structure arranged below the substrate; the second packaging structure comprises a chip, interposer and a molding material; a conductive structure array is arranged on an upper surface of the interposer; the interposer is arranged below the substrate through the conductive structure array; a space region among a lower surface of the substrate, the chip and the interposer is filled with the molding material; a conductive bonding pad array is arranged on the lower surface of the interposer; and a groove is formed in a part of region between the conductive bonding pad and an edge contour of the interposer.

A semiconductor chip includes an active element on a first surface of a substrate. A heat-conductive film having a higher thermal conductivity than the substrate is disposed at a position different from a position of the active element. An insulating film covering the active element and heat-conductive film is disposed on the first surface. A bump electrically connected to the heat-conductive film is disposed on the insulating film. A via-hole extends from a second surface opposite to the first surface to the heat-conductive film. A heat-conductive member having a higher thermal conductivity than the substrate is continuously disposed from a region of the second surface overlapping the active element in plan view to an inner surface of the via-hole. The bump is connected to a land of a printed circuit board facing the first surface. The semiconductor chip is sealed with a resin.

An analog time delay filter circuit including a first delay circuit block arranged in a modular layout, having a first time delay filter, a first input, a first output, and first and second pass-throughs; and a second delay circuit block arranged in the same modular layout, having a second time delay filter, a second input, a second output, and third and fourth pass-throughs.