A conductive member constituting a wiring structure includes a first bonding section bonded to an electronic component, a second bonding section bonded to a connection target for the electronic component, and a raised section that protrudes upward from the first bonding section and is connected to the second bonding section. The conductive member has a wire member passage through which a wire member passes, and which is provided in at least a part of the raised section. The wire member passage enables the wire member to be disposed along the raised section from the first bonding section to the second bonding section such that the wire member intersects a surface of the raised section.

In one example, a semiconductor structure or device comprises a substrate comprising a conductive structure having a top side and a first shielding terminal on the top side of the conductive structure, an electronic component on the top side of the conductive structure, a package body on the top side of the conductive structure and contacting a side of the electronic component, a shield on a top side of the package body and a lateral side of the package body, and a shield interconnect coupling the shield to the first shielding terminal of the conductive structure. Other examples and related methods are also disclosed herein.

According to one embodiment, a semiconductor chip includes a first electrode, a semiconductor layer, a second electrode, a third electrode, and a metallic layer. The semiconductor layer includes a first portion, a second portion, and a third portion that is located between the first portion and the second portion. The semiconductor layer is provided on a first side of the first electrode in a first direction. The second electrode is over the first portion in the first direction. The third electrode is over the second portion in the first direction. The metallic layer is provided on a second side of the first electrode and is under the third portion in the first direction.

A semiconductor device includes: a main wiring wire electrically connected to a semiconductor element; a reinforcing wire connected to the semiconductor element, the reinforcing wire positioned on the same side as the semiconductor element or on the opposite side of the semiconductor element, with respect to the main wiring wire in a cross-sectional view; and a sealing resin configured to cover the semiconductor element, the main wiring wire, and the reinforcing wire. The reinforcing wire is connected to a plurality of portions of the semiconductor element, or both end portions of the reinforcing wire are positioned inside an outline of the semiconductor element in a plan view.

Systems, devices, and methods for high die stack packages with modular structures are provided herein. A die stack package can include a substrate, a proximal unit carried by the substrate, and a distal unit carried by the proximal unit. The proximal unit can include first and second proximal die stacks, a proximal portion of a modular structure, and proximal wire bonds electrically coupling the first and second proximal die stacks to conducting elements of the modular structure. The distal unit can include first and second distal die stacks, a distal portion of the modular structure, and distal wire bonds electrically coupling the first and second distal die stacks to the conducting elements of the modular structure. In some embodiments, the die stack package further includes one or more modular units stacked between the proximal unit and the distal unit.

The package-on-package (POP) structure includes a first package unit of three-dimensional fan-out memory chips and a SiP package unit of the two-dimensional fan-out peripheral circuit chip. The first package unit includes: memory chips laminated in a stepped configuration; a molded substrate; wire bonding structures; a first rewiring layer; a first encapsulating layer; and first metal bumps, formed on the first rewiring layer. The SiP package unit includes: a second rewiring layer; a peripheral circuit chip; a third rewiring layer, bonded to the circuit chip; first metal connection pillars; a second encapsulating layer for the circuit chip and the first metal connection pillars; and second metal bumps on the second rewiring layer. The first metal bumps are bonded to the third rewiring layer. Integrating the two package units into the POP is enabled by three rewiring layers and the molded substrate which supports the first package unit during wire bonding process.

A semiconductor package includes a substrate; a sub semiconductor package disposed over the substrate, the sub semiconductor package including a sub semiconductor chip with chip pads on its active surface that faces the substrate, a sub molding layer that surrounds side surfaces of the sub semiconductor chip, the sub molding layer with a surface that faces the substrate, and redistribution conductive layers that connect to the chip pads and extend under the surface of the sub molding layer, wherein the redistribution conductive layers include a signal redistribution conductive layer that extends toward an edge of the sub molding layer, the signal redistribution conductive layer with a signal redistribution pad on its end portion, and a power redistribution conductive layer that has a length that is shorter than a length of the signal redistribution conductive layer, the power redistribution conductive layer with a power redistribution pad on its end portion; a signal sub interconnector with an upper surface that is connected to the signal redistribution pad and a lower surface that is connected to the substrate; a power sub interconnector with an upper surface that is connected to the power redistribution pad and a lower surface that is connected to the substrate; and at least one main semiconductor chip formed over the sub semiconductor package and electrically connected to the substrate.

A semiconductor package includes; a redistribution wiring layer, a controller chip centrally disposed on the redistribution wiring layer, a first sealant disposed on the redistribution wiring layer, wherein the controller chip is buried in the first sealant, through vias connected to the redistribution wiring layer through the first sealant, and a sub-package disposed on an upper surface of the first sealant. The sub-package may include a first stack structure disposed to one side of the controller chip on the upper surface of the first sealant and including vertically stacked chips, a second stack structure disposed to another side of the controller chip on the upper surface of the first sealant adjacent to the first stack structure in a first horizontal direction and including vertically stacked chips, and a second sealant sealing the first stack structure and the second stack structure.

A package structure includes a leadframe, at least two dies, at least one spacer and a plastic package material. The leadframe includes a die pad. The dies are disposed on the die pad of the leadframe. The spacer is disposed between at least one of the dies and the die pad. The plastic package material is disposed on the leadframe, and covers the dies. A first minimum spacing distance is between one of a plurality of edges of the spacer and one of a plurality of edges of the die pad, a second minimum spacing distance is between one of a plurality of edges of the dies and one of the edges of the die pad, and the first minimum spacing distance is larger than the second minimum spacing distance.

A semiconductor device package and a method of manufacturing a semiconductor device package are provided. The semiconductor device package includes a carrier, a first component, a second component, and a protective element. The first component and the second component are arranged side by side in a first direction over the carrier. The protective element is disposed over a top surface of the carrier and extending from space under the first component toward a space under the second component. The protective element includes a first portion and a second portion protruded oppositely from edges of the first component by different distances, and the first portion and the second portion are arranged in a second direction angled with the first direction.