An exemplary hearing device includes a housing and a chip package disposed within the housing. The chip package may comprise a printed circuit board, an integrated circuit configured to perform an electronic function associated with the hearing device, and a plurality of solder bumps on a bottom surface of the integrated circuit. The plurality of solder bumps may provide conductive connectivity between the integrated circuit and the printed circuit board. The plurality of solder bumps may comprise a first group of solder bumps located within a center region of the bottom surface of the integrated circuit and a second group of solder bumps located within a peripheral region of the bottom surface, the peripheral region surrounding the center region. All signals required for the integrated circuit to perform the electronic function may be provided by way of the first group of solder bumps.

The present disclosure provides an electronic device, which includes an encapsulant, an electronic component, an antenna structure, and a first conductive element. The electronic component is disposed in the encapsulant. The antenna structure has an antenna pattern exposed to air and facing the encapsulant, and a first supporting element separating the antenna pattern from the encapsulant. At least a portion of the first conductive element is within the encapsulant, and electrically connects the antenna pattern to the electronic component by the first supporting element.

In one example, an electronic device comprises a substrate comprising a conductive structure and a dielectric structure, the dielectric structure comprising an upper dielectric layer, an electronic component over a top side of the substrate and coupled with the conductive structure, an encapsulant over the top side of the substrate and adjacent a lateral side of the electronic component, and a shield over the top side of the electronic component and contacting a lateral side of the encapsulant and a first lateral side of the substrate. The conductive structure comprises a first tab structure at the first lateral side of the substrate, and wherein the first tab structure contacts the shield and extends above the upper dielectric layer. Other examples and related methods are also disclosed herein.

A method of manufacturing an electronic device includes: providing a vapor generating chamber that accommodates a heat transfer fluid; providing a substrate stage within the vapor generating chamber, the substrate stage including a seating surface and suction passages penetrating the substrate stage to be open to the seating surface; loading a substrate on the substrate stage, wherein electronic components are disposed on the substrate via bumps; generating at least a partial vacuum in the suction holes to suction-support the substrate on the seating surface; heating the heat transfer fluid to generate saturated vapor within the vapor generating chamber; and soldering the bumps using the saturated vapor.

A structure includes an Sn layer or an Sn alloy layer formed above a substrate, and an under barrier metal formed between the substrate and the Sn layer or Sn alloy layer. The under barrier metal is an Ni alloy layer containing Ni, and at least one selected from W, Ir, Pt, Au, and Bi, and can sufficiently inhibit generation of an intermetallic compound through a reaction, caused due to metal diffusion of a metal contained in the substrate, between the metal and Sn contained in the Sn layer or Sn alloy layer.

The semiconductor structure includes a die structure including: a substrate, a first dielectric disposed over the substrate, a first interconnect structure disposed within the first dielectric, a second dielectric disposed on the first dielectric, and a conductive pad surrounded by the second dielectric; a capping member surrounding the die structure; and an insulating member surrounding the capping member, wherein the capping member includes a first oxynitride layer in contact with the die structure or the insulating member.

A method for manufacturing an electronic package comprises providing at least one electronic component, the at least one electronic component including at least one non-groundable thermal output, providing a substrate in which a ground plane is enclosed in or supported by the substrate, defining at least one thermally conductive pathway extending between an interface exposed on the substrate and the ground plane such that the interface is electrically isolated from the ground plane, and mounting the electronic component to the substrate, the mounting including thermally coupling the output to the interface with at least one thermally conductive member.

A semiconductor package structure includes a redistribution structure layer, at least one chip, an encapsulant, and multiple solder balls. The redistribution structure layer includes multiple first connectors located on a first side. Each first connector includes a connecting pad, a soldering pad, and multiple conductive blind holes located between the connecting pad and the soldering pad. The conductive blind holes are disposed separately from each other and connect the connecting pad and the soldering pad. The chip is disposed on a second side of the redistribution structure layer and electrically connected to the redistribution structure layer. The encapsulant is disposed on the second side and at least covers the chip and the second side. The solder balls are disposed on the first side of the redistribution structure layer and electrically connected to the redistribution structure layer. The solder balls are respectively connected to the connecting pad of each first connector.

A method of manufacturing a semiconductor package may include disposing, in a lower mold, a substrate strip in which a plurality of semiconductor chips are arranged in a horizontal direction, providing, in an upper mold, a release film to which a first encapsulant is attached, allowing the upper mold and the lower mold to be proximate to each other such that a first encapsulant is adjacent to an upper surface of each of the plurality of semiconductor chips, injecting a second encapsulant into a space between the upper mold and the lower mold, heating the first encapsulant and the second encapsulant to form a molded structure including a first encapsulating layer and a second encapsulating layer, allowing the upper mold and the lower mold to be spaced from each other such that the molded structure is separated from the release film, and cutting the molded structure.

A semiconductor package includes a redistribution structure, a first semiconductor chip above the redistribution structure, a second semiconductor chip on, and offset relative to, the first semiconductor chip, a plurality of first conductive posts extending from a bottom surface of the second semiconductor chip to a top surface of the redistribution structure, a third semiconductor chip on the second semiconductor chip, a plurality of second conductive posts extending from a bottom surface of the third semiconductor chip to the top surface of the redistribution structure, and a molding layer between the top surface of the redistribution structure and the bottom surface of the third semiconductor chip.