A semiconductor package includes a first sub-semiconductor package, an interposer substrate, and a second sub-semiconductor package that are sequentially stacked. The first sub-semiconductor package includes a first package substrate, a first semiconductor device, and a first mold member that are sequentially stacked, and the interposer substrate includes at least one hole. The first mold member includes: a mold main portion which covers the first semiconductor device; a mold connecting portion extended from the mold main portion and inserted into the at least one hole; and a mold protruding portion extended from the mold connecting portion to cover a top surface of the interposer substrate outside the at least one hole. The mold main portion, the mold connecting portion, and the mold protruding portion constitute a single object.

An electronic control module includes: a first board having an upper surface on which electronic components are mounted; a second board disposed on an upper surface side of the first board with an interval therebetween and having an upper surface on which electronic components are mounted; and a tubular bracket provided between the first board and the second board and defining a closed space between the first board and the second board.

The present disclosure provides a semiconductor structure including a first substrate having a first surface, a first semiconductor device package disposed on the first surface of the first substrate, and a second semiconductor device package disposed on the first surface of the first substrate. The first semiconductor device package and the second semiconductor device package have a first signal transmission path through the first substrate and a second signal transmission path insulated from the first substrate. The present disclosure also provides an electronic device.

A method includes attaching a first die and a second die to a carrier; forming a molding material between the first die and second die; and forming a redistribution structure over the first die, the second die and the molding material, the redistribution structure includes a first redistribution region; a second redistribution region; and a dicing region between the first redistribution region and the second redistribution region. The method further includes forming a first opening and a second opening in the dicing region, the first opening and the second opening extending through the redistribution structure and exposing the molding material; and separating the first die and the second die by cutting through a portion of the molding material aligned with the dicing region from a second side of the molding material toward the first side of the molding material, the second side opposing the first side.

A substrate structure may include a printed circuit board including a first recess and a first junction pad disposed on a lower surface of the first recess; a first electronic component package disposed in the first recess, and including a first substrate and a first electronic device module disposed on at least one surface of the first substrate; and a first external junction portion connecting the first electronic component package and the first junction pad.

A package comprises at least one first device die, and a redistribution line (RDL) structure having the at least one first device die bonded thereto. The RDL structure comprises a plurality of dielectric layers, and a plurality of RDLs formed through the plurality of dielectric layers. A trench is defined proximate to axial edges of the RDL structure through each of the plurality of dielectric layers. The trench prevents damage to portions of the RDL structure located axially inwards of the trench.

A semiconductor device has a conductive via laterally separated from the semiconductor, an encapsulant between the semiconductor device and the conductive via, and a mark. The mark is formed from characters that are either cross-free characters or else have a overlap count of less than two. In another embodiment the mark is formed using a wobble scan methodology. By forming marks as described, defects from the marking process may be reduced or eliminated.

Embodiments disclosed herein include an electronics package. In an embodiment, the electronics package comprises a package substrate and a die on the package substrate. In an embodiment, a mold layer is positioned over the package substrate. In an embodiment, the electronics package further comprises through-mold interconnects through the mold layer, and a trench that extends at least partially into the mold layer.

A semiconductor device has a conductive via laterally separated from the semiconductor, an encapsulant between the semiconductor device and the conductive via, and a mark. The mark is formed from characters that are either cross-free characters or else have a overlap count of less than two. In another embodiment the mark is formed using a wobble scan methodology. By forming marks as described, defects from the marking process may be reduced or eliminated.

An example of a printable electronic component includes a component substrate having a connection post side and an opposing contact pad side. The component can include one or more non-planar, electrically conductive connection posts protruding from the connection post side of the component substrate. Each of the one or more connection posts can have a peak area smaller than a base area. The component can include one or more non-planar, electrically conductive exposed component contact pads disposed on (e.g., directly on, indirectly on, or in) the contact pad side of the component substrate. Multiple components can be stacked such that connection post(s) of one are in contact with non-planar contact(s) of one or more others.