Microelectronic devices and methods for manufacturing such devices are disclosed herein. In one embodiment, a packaged microelectronic device can include an interposer substrate with a plurality of interposer contacts. A microelectronic die is attached and electrically coupled to the interposer substrate. The device further includes a casing covering the die and at least a portion of the interposer substrate. A plurality of electrically conductive through-casing interconnects are in contact with and projecting from corresponding interposer contacts at a first side of the interposer substrate. The through-casing interconnects extend through the thickness of the casing to a terminus at the top of the casing. The through-casing interconnects comprise a plurality of filaments attached to and projecting away from the interposer contacts in a direction generally normal to the first side of the interposer substrate.

A semiconductor package includes upper and lower semiconductor chip packages, and a redistribution wiring layer pattern interposed between the packages. The lower package includes a molding layer in which at least one chip is embedded, and has a top surface and an inclined sidewall surface along which the redistribution wiring layer pattern is formed. The upper and lower packages are electrically connected to through the redistribution wiring layer pattern. A first package may be formed by a wafer level packaging technique and may include a redistribution wiring layer as a substrate, a semiconductor chip disposed on the redistribution wiring layer, and a molding layer on which the lower package, redistribution wiring layer pattern and upper package are disposed.

A semiconductor device is disclosed mounted at an angle on a signal carrier medium such as a printed circuit board. The semiconductor device includes a stack of semiconductor die stacked in a stepped offset configuration. The die stack may then be encapsulated in a block of molding compound. The molding compound may then be singulated with slanted cuts along two opposed edges. The slanted edge may then be drilled to expose the electrical contacts on each of the semiconductor die. The slanted edge may then be positioned against a printed circuit board having solder or other conductive bumps so that the conductive bumps engage the semiconductor die electrical contacts in the drilled holes. The device may then be heated to reflow and connect the electrical contacts to the conductive bumps.

Microelectronic die packages, stacked systems of die packages, and methods of manufacturing them are disclosed herein. In one embodiment, a system of stacked packages includes a first die package having a bottom side, a first dielectric casing, and first metal leads; a second die package having a top side attached to the bottom side of the first package, a dielectric casing with a lateral side, and second metal leads aligned with and projecting towards the first metal leads and including an exterior surface and an interior surface region that generally faces the lateral side; and metal solder connectors coupling individual first leads to individual second leads. In a further embodiment, the individual second leads have an L shape and physically contact corresponding individual first leads. In another embodiment, the individual second leads have a C shape and include a tiered portion that projects towards the lateral side of the second casing.

In accordance with some embodiments of the present disclosure, a packaged semiconductor device includes a first package structure, at least one outer conductive bump, a second package structure, a sealing material, and an electromagnetic interference (EMI) shielding layer. The first package structure has a first cut edge. The outer conductive bump is disposed on the first package structure and has a second cut edge. The second package structure is jointed onto the first package structure. The sealing material is disposed on the first package structure, surrounds the second package structure, and covers the outer conductive bump. The sealing material has a third cut edge. The EMI shielding layer contacts the first cut edge, the second cut edge and the third cut edge. The EMI shielding layer is electrically connected with the outer conductive bump.

Microelectronic die packages, stacked systems of die packages, and methods of manufacturing them are disclosed herein. In one embodiment, a system of stacked packages includes a first die package having a bottom side, a first dielectric casing, and first metal leads; a second die package having a top side attached to the bottom side of the first package, a dielectric casing with a lateral side, and second metal leads aligned with and projecting towards the first metal leads and including an exterior surface and an interior surface region that generally faces the lateral side; and metal solder connectors coupling individual first leads to individual second leads. In a further embodiment, the individual second leads have an L shape and physically contact corresponding individual first leads. In another embodiment, the individual second leads have a C shape and include a tiered portion that projects towards the lateral side of the second casing.

The semiconductor package according to the present invention comprises: an integrated substrate; a bottom chip stack, which is mounted on the integrated substrate, has multiple memory semiconductor dies stacked chip-on-chip, and takes charge of a part of the whole memory capacity; at least one top chip stack, which is mounted on the bottom package, has multiple memory semiconductor dies mounted therein, and takes charge of the rest of the whole memory capacity; an integration wire for electrically connecting the bottom chip stack and the top chip stack(s); and an integration protection member for sealing the integration wire.

Packaged semiconductor assemblies including interconnect structures and methods for forming such interconnect structures are disclosed herein. One embodiment of a packaged semiconductor assembly includes a support member having a first bond-site and a die carried by the support member having a second bond-site. An interconnect structure is connected between the first and second bond-sites and includes a wire that is coupled to at least one of the first and second bond-sites. The interconnect structure also includes a third bond-site coupled to the wire between the first and second bond-sites.

An electrical structural member comprises a first package and a second package. The first package has a first connection frame, a chip disposed in the first connection frame, and a first encapsulation material encapsulating the chip and at least portions of the first connection frame. The second package has a second connection frame and a second encapsulation material encapsulating at least portions of the second connection frame. The first encapsulation material is securely connected to the second encapsulation material.

An electronic system supports superior coupling by implementing a communication mechanism that provides at least for horizontal communication for example, on the basis of wired and/or wireless communication channels, in the system. Hence, by enhancing vertical and horizontal communication capabilities in the electronic system, a reduced overall size may be achieved, while nevertheless reducing complexity in printed circuit boards coupled to the electronic system. In this manner, overall manufacturing costs and reliability of complex electronic systems may be enhanced.