A semiconductor package includes a package substrate including a first substrate channel pad and a second substrate channel pad, a chip stack including a plurality of semiconductor chips stacked on the package substrate to be offset in a first direction, wherein first semiconductor chips located on odd layers from among the plurality of semiconductor chips and second semiconductor chips located on even layers from among the plurality of semiconductor chips are offset in a second direction perpendicular to the first direction, each of the first semiconductor chips includes a first chip channel pad, and each of the second semiconductor chips includes a second chip channel pad, first inter-chip connection wires configured to electrically connect the first chip channel pads of the first semiconductor chips to one another, second inter-chip connection wires configured to electrically connect the second chip channel pads of the second semiconductor chips to one another.

A semiconductor device includes a semiconductor element made up of a semiconductor substrate, an element electrode formed on the substrate, and a wiring layer electrically connected to the element electrode. The semiconductor device further includes a lead frame supporting the semiconductor element, a first conductive member electrically connecting the semiconductor element and the lead frame, a second conductive member overlapping with the semiconductor element as seen in plan view, and a sealing resin covering the semiconductor element, a part of the lead frame, and the first and second conductive member. The wiring layer includes a first pad portion and a second pad portion. The second conductive member has a first connecting portion bonded to the first pad portion and a second connecting portion bonded to the second pad portion.

A semiconductor device includes a semiconductor element made up of a semiconductor substrate, an element electrode formed on the substrate, and a wiring layer electrically connected to the element electrode. The semiconductor device further includes a lead frame supporting the semiconductor element, a first conductive member electrically connecting the semiconductor element and the lead frame, a second conductive member overlapping with the semiconductor element as seen in plan view, and a sealing resin covering the semiconductor element, a part of the lead frame, and the first and second conductive member. The wiring layer includes a first pad portion and a second pad portion. The second conductive member has a first connecting portion bonded to the first pad portion and a second connecting portion bonded to the second pad portion.

A semiconductor device is disclosed including a wire bonded die stack where the bond wires skip dies in the die stack to provide bond wires having a long length. In one example, the semiconductor dies are stacked on top of each other with offsets along two orthogonal axes so that the dies include odd numbered dies interspersed and staggered with respect to even numbered dies only one of the axes. Wire bonds may be formed between the odd numbered dies, skipping the even numbered dies, and wire bonds may be formed between the even numbered dies, skipping the odd numbered dies. The long length of the bond wires increases an inductance of the wire bonds relative to parasitic capacitance of the semiconductor dies, thereby increasing signal path bandwidth of the semiconductor device.

In one example, an electronic device structure includes a substrate having a conductive structure adjacent to a surface. The conductive structure can include a plurality of conductive pads. First and second electronic devices are disposed adjacent to the top surface. The first electronic device is interposed between a first conductive pad and a second conductive pad, and the second electronic device is interposed between the second conductive pad and a third conductive pad. A continuous wire structure including a first bond structure is connected to the first conductive pad, a second bond structure is connected to the second conductive pad, a third bond structure is connected to the third conductive pad, a first wire portion is interconnected between the first bond structure and the second bond structure and disposed to overlie the first electronic device, and a second wire portion is interconnected between the second bond structure and the third bond structure and disposed to overlie the second electronic device. Other examples and related methods are also disclosed herein.

A light emitting device includes: a base comprising a first lead, a second lead, and a supporting member; a light emitting element mounted on the first lead; a protection element mounted on the second lead; a wire including a first end and a second end, wherein the first end is connected to an upper surface of the first lead, and the second end is connected to a first terminal electrode of the protection element; a resin frame located on an upper surface of the base, wherein the resin frame covers at least part of the protection element and surrounds the light emitting element and the first end of the wire; a first resin member surrounded by the resin frame and covering the light emitting element and the first end of the wire; and a second resin member covering the resin frame and the first resin member.

The disclosure relates to a dual-interface integrated circuit (IC) card module for use in a dual-interface IC card. Embodiments disclosed include a dual-interface integrated circuit card module (150), the module comprising: a substrate (104) having first and second opposing surfaces; a contact pad (102) on the first surface of the substrate; an integrated circuit (110) on the second surface of the substrate (104), the integrated circuit (110) having electrical connections to the contact pad (102) through the substrate (104); and a pair of antenna pads (108) disposed in recesses (103) in the second surface of the substrate (104) and electrically connected to corresponding antenna connections on the integrated circuit (110).

A flip-chip integrated circuit die includes a front side including active circuitry formed therein and a plurality of bond pads in electrical communication with the active circuitry, at least two through-wafer vias extending at least partially though the die and having portions at a rear side of the die, and a bond wire external to the die and electrically coupling the portions of the at least two through-wafer vias at the rear side of the die.

A flip-chip integrated circuit die includes a front side including active circuitry formed therein and a plurality of bond pads in electrical communication with the active circuitry, at least two through-wafer vias extending at least partially though the die and having portions at a rear side of the die, and a bond wire external to the die and electrically coupling the portions of the at least two through-wafer vias at the rear side of the die.

Disclosed are a semiconductor device and a stacked semiconductor package. The semiconductor device may include a semiconductor chip and a plurality of chip pads disposed on the semiconductor chip in a second horizontal direction perpendicular to a first horizontal direction. The plurality of chip pads may include: a first chip pad connected to a wire extending in the first horizontal direction, when seen from the top; and a second chip pad connected to a diagonal wire extending in a direction at an angle to the first and second horizontal directions, when seen from the top. The width of the first chip pad in the second horizontal direction may be smaller than the width of the second chip pad in the second horizontal direction.