A method of manufacturing a semiconductor package of stacked semiconductor chips includes forming a reverse wire bond by bonding one end of a reverse wire to a chip pad of the second-highest semiconductor chip of the stacked semiconductor chips and connecting the other end of the reverse wire to a conductive bump on a chip pad of the uppermost semiconductor chip of the stacked semiconductor chips. The method also includes molding the stacked semiconductor chips with the reverse wire bond using a mold layer. The method further includes processing the mold layer to expose the conductive bump and the other end of the reverse wire in the reverse wire bond through an upper surface of the mold layer.

A power chip packaging structure includes: a ceramic substrate; a first and a second top metal layers are formed on the ceramic substrate; a bottom metal layer formed on the ceramic substrate; a power chip having an active surface and a chip back surface. The active surface has a contact pad, and the chip back surface is connected to the first top metal layer. One or more first copper layers are formed on the contact pad, a top surface of the first copper layer has a peripheral region and an arrangement region surrounded by the peripheral region. Multiple second copper layers are formed in the arrangement region and separated from each other. Each of multiple wires is respectively connected to the second copper layer with one end and connected to the second top metal layer with the other end.

An electronic device includes: an insulating substrate including an obverse surface facing a thickness direction; a wiring portion formed on the substrate obverse surface and made of a conductive material; a lead frame arranged on the substrate obverse surface; a first and a second semiconductor elements electrically connected to the lead frame; and a first control unit electrically connected to the wiring portion to operate the first semiconductor element as a first upper arm and operate the second semiconductor element as a first lower arm. The lead frame includes a first pad portion to which the first semiconductor element is joined and a second pad portion to which the second semiconductor element is joined. The first and second pad portions are spaced apart from the wiring portion and arranged in a first direction with a first separation region sandwiched therebetween, where the first direction is orthogonal to the thickness direction. The first control unit is spaced apart from the lead frame as viewed in the thickness direction, while overlapping with the first separation region as viewed in a second direction orthogonal to the thickness direction and the first direction.

A recording element unit includes a first electrode pad, a second electrode pad, and a wire for electrically connecting the first electrode pad and the second electrode pad. The wire has a plurality of bending points at which the wire is bent in the direction of extension of the wire between a first connection point and a second connection point. The plurality of bending points include a first bending point at a height from the first connection point of at least 100 m and not more than 200 m, a second bending point at a distance from the first bending point in the horizontal direction of at least 100 m and not more than 270 m, and a third bending point at a distance from the intermediate point between the first electrode pad and the second electrode pad in the horizontal direction of within 150 m.

A semiconductor device according to one aspect includes a pad portion, an insulating layer that supports the pad portion, a first wiring layer that is formed in a layer below the pad portion and extends in a first direction below the pad portion, and a conductive member that is joined to a front surface of the pad portion and extends in a direction forming an angle of 30 to 30 with respect to the first direction. A semiconductor device according to another aspect includes a pad portion, an insulating layer that supports the pad portion, a first wiring layer that is formed in a layer below the pad portion and extends in a first direction below the pad portion, and a conductive member that is joined to a front surface of the pad portion and has a joint portion that is long in one direction in plan view and an angle of a long direction of the joint portion with respect to the first direction is 30 to 30.

A storage device includes a substrate of a memory package and a first memory die. The substrate includes a controller and a first pin pad, the first pin pad being electrically connected to the controller and defining a data channel for data communications. The first memory die includes a front pin pad electrically connected to the first pin pad of the substrate by way of a first bond wire, a rear pin pad, a redistribution layer electrically connecting the front pin pad and the rear pin pad of the first memory die, and a plurality of memory cells configured to provide non-volatile storage accessible by way of the data channel.

A semiconductor device includes a mounting substrate having a first surface, a semiconductor chip mounted on the first surface and having a second surface facing a side opposite to the first surface, and a wire extending from a first joint point on the first surface toward a second joint point on the second surface and electrically connecting the mounting substrate and the semiconductor chip to each other by connecting the first joint point and the second joint point to each other. The wire includes a first part, a first bent portion, a second part, a second bent portion, and a third part arranged in order from the first joint point toward the second joint point. The first part is positioned on the first surface side with respect to the second surface when viewed in a first direction along the first surface and the second surface.

A die including a die body having a first body surface, a second body surface on an opposite side of the die body as the first body surface, an interconnect region adjacent to the first body surface including interconnect dielectric layers with metal lines and vias, a transistor region above the interconnect region, the metal lines and vias making electrical connections to one or more power rails of the transistor region and electrically connected to transistors of the transistor region, a power region above the transistor region including an electro-conductive film on the second body surface and TSVs in the power region, an outer end of the TSV contacting the film and an embedded end of the TSVs contacting one of the power rails. A method of manufacturing an IC package and computer with the IC package are also disclosed.