The semiconductor device includes a semiconductor element, a first lead, and a second lead. The semiconductor element has an element obverse surface and an element reverse surface spaced apart from each other in a thickness direction. The semiconductor element includes an electron transit layer disposed between the element obverse surface and the element reverse surface and formed of a nitride semiconductor, a first electrode disposed on the element obverse surface, and a second electrode disposed on the element reverse surface and electrically connected to the first electrode. The semiconductor element is mounted on the first lead, and the second electrode is joined to the first lead. The second lead is electrically connected to the first electrode. The semiconductor element is a transistor. The second lead is spaced apart from the first lead and is configured such that a main current to be subjected to switching flows therethrough.

An integrated circuit (IC) comprising an enhanced passivation scheme for pad openings and trenches is provided. In some embodiments, an interlayer dielectric (ILD) layer covers a substrate and at least partially defines a trench. The trench extends through the ILD layer from a top of the ILD layer to the substrate. A conductive pad overlies the ILD layer. A first passivation layer overlies the ILD layer and the conductive pad, and further defines a pad opening overlying the conductive pad. A second passivation layer overlies the ILD layer, the conductive pad, and the first passivation layer, and further lines sidewalls of the first passivation layer in the pad opening and sidewalls of the ILD layer in the trench. Further, the second passivation layer has a low permeability for moisture or vapor relative to the ILD layer.

A semiconductor device and a lead frame. The semiconductor device comprises at least one semiconductor chip that is attached to a surface of a base island in a first plane, wherein a connecting rib is connected to the base island, and has a first part which is obliquely connected to the base island; the connecting rib has a second part, and the second part has a surface in a second plane; the second plane is parallel to the first plane and is a plane different from the first plane; the connecting rib has a branch part divided from the second part and the branch part has, in the second plane, a surface used for receiving a lead connected to the semiconductor chip; and the branch part has an edge which is distant from a first edge of the base island by a first distance.

In an optical receiver circuit which suppresses an unnecessary increase in impedance and occurrences of resonance and radiation noise and which produces preferable high-frequency transmission characteristics, a PD submount mounted with a PD chip and a chip capacitor and a TIA carrier mounted with a TIA chip are electrically connected to each other by a bonding wire. The chip includes an anode electrode pad and a cathode electrode pad, anode electrode-side ground pads are formed at positions that sandwich the pad, and cathode electrode-side ground pads are formed at positions that sandwich the pad. A wire electrically connects the pad and a signal pad for input of the chip to each other, a wire electrically connects the pad and the capacitor to each other, and a wire electrically connects the pads and the pads to each other.

Isolators for signals and/or powers transmitted between two circuits configured to operate at different voltage domains are provided. The isolators may have working voltages, for example, higher than 500 Vrms, higher than 1000 Vrms, or between 333 Vrms and 1800 Vrms. The isolators may have a fully symmetrical configuration. The isolators may include a primary winding coupled to a driver and a secondary winding coupled to a receiver. The primary and secondary windings may be laterally coupled to and galvanically isolated from each other. The primary and secondary windings may include concentric traces. The primary and secondary windings may be fabricated using a single metallization layer on a substrate.

A light emitting device includes: a base having a first stepped portion and a second stepped portion; a light emitting element; an electronic member configured to be irradiated by light emitted from the light emitting element; a first wiring region located on the first stepped portion; a second wiring region located on the second stepped portion; wires connected to the light emitting element and the electronic member. The wires includes a first and second wires. The first wire has a first end that is connected to the first wiring region, and a second end. The second wire has a first end that is connected to the second wiring region, and a second end. A position of the second end of the first wire relative to the bottom face is lower than a position of the second end of the second wire relative to the bottom face.

A method of manufacturing a semiconductor device is provided. The method includes attaching a first end of a first bond wire to a first conductive lead and a second end of the first bond wire to a first bond pad of a first semiconductor die. A conductive lead extender is affixed to the first conductive lead by way of a conductive adhesive, the lead extender overlapping the first end of the first bond wire. A first end of a second bond wire is attached to the lead extender, the first end of the second bond wire conductively connected to the first end of the first bond wire.

Disclosed is a semiconductor package comprising a first chip stack including on a substrate a plurality of first semiconductor chips in an offset stack structure and stacked to expose a connection region at a top surface of each of the first semiconductor chips, a second semiconductor chip on the substrate and horizontally spaced apart from the first chip stack, a spacer on the second semiconductor chip, and a second chip stack including third semiconductor chips in an offset stack structure on the first chip stack and the spacer. Each of the first semiconductor chips includes a first chip pad on the connection region and a first wire that extends between the first chip pad and the substrate. The first wire of an uppermost one of the first semiconductor chips is horizontally spaced apart from a lowermost one of the third semiconductor chips.

A semiconductor package includes a second semiconductor chip disposed on a first semiconductor chip. The first semiconductor chip includes a first semiconductor substrate, a through via, and a lower pad disposed on the through via. The lower pad includes a first segment and a second segment connected thereto. The first segment overlaps the through via. The second segment is disposed on an edge region of the first segment. The second segment has an annular shape. The second semiconductor chip includes a second semiconductor substrate, an upper pad disposed on a bottom surface of the second semiconductor substrate, and a connection terminal disposed between the upper and lower pads. The second segment at least partially surrounds a lateral surface of the upper pad. A level of a top surface of the second segment is higher than that of an uppermost portion of the connection terminal.

A semiconductor package having a die with a sidewall protected by molding compound, and methods of forming the same are disclosed. The package includes a die with a first surface opposite a second surface and sidewalls extending between the first and second surfaces. A redistribution layer is formed on the first surface of each die. An area of the first surface of the die is greater than an area of the redistribution layer, such that a portion of the first surface of the die is exposed. When molding compound is formed over the die and the redistribution layer to form a semiconductor package, the molding compound is on the first surface of the die between an outer edge of the redistribution layer and an outer edge of the first surface. The molding compound is also on the sidewalls of the die, which provides protection against chipping or cracking during transport.