Methods of forming microelectronic package structures/modules, and structures formed thereby, are described. Structures formed herein may include a second die disposed on a first die, a first plurality of interconnect structures disposed on a top surface of the first die, and a second plurality of interconnect structures disposed on a top surface of the second die. Top surfaces of the first plurality of interconnect structures are coplanar with top surfaces of the plurality of the second interconnect structures. At least one of the interconnect structures of the first or the second plurality of interconnect structures comprises a sigmoid shape.

Wirebond bondpads on semiconductor packages that result in reduced cross-talk and/or interference between vertical wires are disclosed. The vertical wirebonds may be disposed in the semiconductor package with stacked dies, where the wires are substantially normal to the bondpads to which the vertical wirebonds are attached on the dies. The wirebond pads may include signal pads that carry input/output (I/O) to/from the die package, as well as ground bondpads. The vertical wirebond bondpads may have widths that are greater than the space between adjacent bondpads. Bondpads may be fabricated to be larger than the size requirements for reliable wirebond formation on the bondpads. For a fixed pitch bondpad configuration, the size of the signal bondpads adjacent to the ground bondpads may be greater than half of the pitch. By increasing the size (e.g., width) of the signal bondpads adjacent to a ground line relative to the space therebetween, improved cross-talk performance may be achieved.

Provided is a semiconductor device enabling highly accurate adjustment of a mounting height at a time when the semiconductor device is mounted on an assembly board, and an electronic apparatus. A linear lead is extracted from a bottom surface of a cylindrical resin sealing body covering a semiconductor chip, and a plurality of helical leads are arranged so as to wind around the linear lead, to thereby form a multi-helical structure. The plurality of helical leads forming the multi-helical structure has the same pitch.

A semiconductor device according to an embodiment includes: a die pad including an upper surface; a semiconductor chip provided on the upper surface, the semiconductor chip including a rectangular shape, and the semiconductor chip including an element region, and a termination region surrounding the element region; a first electrode provided on the semiconductor chip; a second electrode provided on the semiconductor chip; a first connector provided above the termination region, the first connector including a portion covering each of the four sides of the rectangular shape when viewed from above, and the first connector being electrically connected to the first electrode; and a sealing resin sealing a periphery of the semiconductor chip and the first connector.

An electronic device made from the method of providing a donor substrate comprising an array of metallic interconnects, using a laser system to prepare the metallic interconnects, forming shaped metallic interconnects, laser bending the shaped metallic interconnects; and transferring the shaped metallic interconnects onto a receiving substrate or device.

A molded lead frame device includes a plurality of lead frame units and a molding layer. Each of the lead frame units includes an array of leads. Each of the leads includes a die-connecting portion and a terminal portion that extends downwardly from the die-connecting portion. The molding layer embeds the die-connecting portions of the lead frame units and has spaced apart longitudinal and transverse sections intersecting each other and separating the lead frame units from each other.

Embodiments of the present disclosure describe integrated circuit (IC) package assemblies having one or more wires that extend beyond a topmost component in the IC package assembly, computing devices incorporating the IC package assemblies, methods for formation of the IC package assemblies, and associated configurations. An IC package assembly may include a substrate having a first side and a second side opposite the first side, an IC die having a first side and a second side opposite the first side, where the first side of the IC die faces the first side of the substrate, a wire electrically coupled with the IC die, where an end of the wire extends beyond a topmost component in the IC package assembly, and an overmold coupled with the topmost component. Other embodiments may be described and/or claimed.

A method of forming and transferring shaped metallic interconnects, comprising providing a donor substrate comprising an array of metallic interconnects, using a laser system to prepare the metallic interconnects, forming shaped metallic interconnects, and transferring the shaped metallic interconnect to an electrical device. An electronic device made from the method of providing a donor ribbon, wherein the donor ribbon comprises an array of metal structures and a release layer on a donor substrate, providing a stencil to the metal structures on the donor substrate, applying a laser pulse through the donor substrate to the metal structures, and directing the metal structures to an electronic device.

A molded lead frame device includes a plurality of lead frame units and a molding layer. Each of the lead frame units includes an array of leads. Each of the leads includes a die-connecting portion and a terminal portion that extends downwardly from the die-connecting portion. The molding layer embeds the die-connecting portions of the lead frame units and has spaced apart longitudinal and transverse sections intersecting each other and separating the lead frame units from each other.

Embodiments of the present disclosure describe integrated circuit (IC) package assemblies having one or more wires that extend beyond a topmost component in the IC package assembly, computing devices incorporating the IC package assemblies, methods for formation of the IC package assemblies, and associated configurations. An IC package assembly may include a substrate having a first side and a second side opposite the first side, an IC die having a first side and a second side opposite the first side, where the first side of the IC die faces the first side of the substrate, a wire electrically coupled with the IC die, where an end of the wire extends beyond a topmost component in the IC package assembly, and an overmold coupled with the topmost component. Other embodiments may be described and/or claimed.