A semiconductor package includes a first connection die including a semiconductor substrate and an interconnect structure, and a first die stack disposed on the first connection die and including stacked dies, each of the stacked dies including a semiconductor substrate and an interconnect structure including a first connection line that is electrically connected to the interconnect structure of the first connection die. An angle formed between a plane of the first connection die and a plane of each stacked die ranges from about 45° to about 90°.

The present invention relates to a module that has a lower component of a module (1) having a material (3) in which at least one first structural element (4) is embedded, and an upper component of a module (2) having a material (3) in which at least a second component (16) is embedded. The upper component of the module (2) and the lower component of the module (1) are stacked, with the lower and the upper component of the module (2) being electrically connected and mechanically linked to each other. In addition, the present invention relates to a simple and cost-effective process for the production of a variety of modules. The invention makes it possible for the modules to be miniaturized with respect to surface and height and/or makes it possible to achieve greater integration by 3D packaging.

Stacked microelectronic devices and methods for manufacturing such devices are disclosed herein. In one embodiment, a stacked microelectronic device assembly can include a first known good packaged microelectronic device including a first interposer substrate. A first die and a first through-casing interconnects are electrically coupled to the first interposer substrate. A first casing at least partially encapsulates the first device such that a portion of each first interconnect is accessible at a top portion of the first casing. A second known good packaged microelectronic device is coupled to the first device in a stacked configuration. The second device can include a second interposer substrate having a plurality of second interposer pads and a second die electrically coupled to the second interposer substrate. The exposed portions of the first interconnects are electrically coupled to corresponding second interposer pads.

Embodiments of a method for fabricating System-in-Packages (SiPs) are provided, as are embodiments of a SiP. In one embodiment, the method includes producing a first package including a first molded package body having a sidewall. A first leadframe is embedded within the first molded package body and having a first leadframe lead exposed through the sidewall. In certain implementations, a semiconductor die may also be encapsulated within the first molded package body. A Surface Mount Device (SMD) is mounted to the sidewall of the first molded package body such that a first terminal of the SMD is in ohmic contact with the first leadframe lead exposed through the sidewall.

A method of forming a quilt package nodule includes forming a trench in a microchip substrate, forming a metal layer on the bottom, the first and second sides of the trench, and on a top surface of the microchip substrate proximate the first and second sides. forming a mask layer on the metal layer, removing portions of the mask and metal layers on the bottom of the trench, etching the bottom of the trench to increase the depth of the bottom of the trench, removing remaining portions of the mask layer from the metal layer to define the quilt package nodules that protrude beyond edges of the first and second sides, and removing the remaining portion of the trench bottom thereby separating the first and second sides from each other, whereupon each side includes at least one quilt package nodule protruding from the side.

A passive device module includes a first tier, a second tier and connective terminals. The first tier includes a first semiconductor chip and a first encapsulant. The first semiconductor chip has contact posts. The encapsulant encapsulates the first semiconductor chip. The second tier is disposed on the first tier, and includes a second semiconductor chip, through interlayer walls, and a second encapsulant. The through interlayer walls are locate beside and face sidewalls of the second semiconductor chip and are electrically connected to the contact posts. The second encapsulant encapsulates the second semiconductor chip and the through interlayer walls. The connective terminals are disposed over the second tier and are electrically connected to the first semiconductor chip via the through interlayer walls. The first and second semiconductor chips include passive devices.

A packaged electronic device includes a package structure with opposite first and second sides spaced apart from one another along a first direction, and opposite third and fourth sides spaced apart from one another along a second direction, as well as first and second leads. The first lead includes a first portion that extends outward from the third side of the package structure and extends downward toward a plane of the first side and away from a plane of the second side. The second lead includes a first portion that extends outward from the third side of the package structure, and the second lead extends upward toward the plane of the second side and away from the plane of the first side to allow connection to another circuit or component, such as a second packaged electronic device, a passive circuit component, a printed circuit board, etc.

An electronic structure includes a packaging structure, a circuit pattern structure, an underfill and a protrusion structure. The circuit pattern structure is disposed over the packaging structure. A gap is between the circuit pattern structure and the packaging structure. The underfill is disposed in the gap. The protrusion structure is disposed in the gap, and is configured to facilitate the distributing of the underfill in the gap.

A semiconductor device package includes a first substrate having an electrical circuit, semiconductor dies stacked one on top of the other, and bond wires electrically connected one to another. The bond wires electrically couple the semiconductor dies to one another and to the electrical circuit. There is a first bond wire having a first portion connected to a first semiconductor die, a second portion connected to a second semiconductor die, and an intermediate portion between the first portion and second portion. The semiconductor device package further includes a molding compound encapsulating the semiconductor dies, and the first and second portions of the first bond wire. The intermediate portion of the first bond wire is exposed along a top planar surface of the molding compound. The semiconductor device package may be used for coupling one or more other semiconductor device packages thereto via the exposed intermediate portion.

A semiconductor memory device includes a substrate that has a first main surface and a second main surface opposite to the first main surface, a first semiconductor chip which is mounted on the first main surface and includes a first register, a plurality of first input/output (IO) terminals, and a first circuit connected between the first IO terminals and the first register, and a second semiconductor chip which is mounted on the second main surface and includes a second register, a plurality of second input/output (IO) terminals, and a second circuit connected between the second IO terminals and the second register. The second circuit is connected to the second IO terminals through input lines and to the second register through output lines, and is configured to change a connection path between the input lines and the output lines in response to a connection change command.