A semiconductor package is provided. The semiconductor package includes: a first redistribution substrate; a semiconductor chip provided on the first redistribution substrate; a molding layer provided on the first redistribution substrate and the semiconductor chip; and a second redistribution substrate provided on the molding layer. The second redistribution substrate includes: redistribution patterns spaced apart from one another; a first dummy conductive pattern spaced apart from the redistribution patterns; an insulating layer provided on the first dummy conductive pattern; and a marking metal layer provided on the insulating layer and spaced apart from the first dummy conductive pattern. Sidewalls of the marking metal layer overlap the first dummy conductive pattern along a vertical direction perpendicular to an upper surface of the first redistribution substrate.

A semiconductor package includes a first chip package including a plurality of first semiconductor dies and a first insulating encapsulant, a second semiconductor die, a third semiconductor die, and a second insulating encapsulant. The plurality of first semiconductor dies are electrically connected to each other, and the first insulating encapsulant encapsulates the plurality of first semiconductor dies. The second semiconductor die and the third semiconductor die are electrically communicated to each other by connecting to the first chip package, wherein the first chip package is stacked on the second semiconductor die and the third semiconductor die. The second insulating encapsulant encapsulates the first chip package, the second semiconductor die, and the third semiconductor die.

The present disclosure provides a fan-out packaging structure and a method for fabricating the fan-out packaging. The fan-out packaging structure includes a first redistribution layer, a second redistribution layer, metal connecting posts, a semiconductor chip, a first filling layer, a first packaging layer, a stacked chip package, a passive element, a second filling layer, a second packaging layer, and metal bumps. By means of the present disclosure, various chips having different functions can be integrated into one packaging structure, thereby improving the integration of the fan-out packaging structure. By means of the first redistribution layer, the second redistribution layer, and the metal connecting posts, a three-dimensional vertical stacked packaging is achieved. In this way, the integration level of the packaging structure can be effectively improved, and the conduction path can be significantly shortened, thereby reducing the power consumption, increasing the signal transmission speed, and increasing the data processing capacity.

A semiconductor package includes a first chip package including a plurality of first semiconductor dies and a first insulating encapsulant, a second semiconductor die, a third semiconductor die, and a second insulating encapsulant. The plurality of first semiconductor dies are electrically connected to each other, and the first insulating encapsulant encapsulates the plurality of first semiconductor dies. The second semiconductor die and the third semiconductor die are electrically communicated to each other by connecting to the first chip package, wherein the first chip package is stacked on the second semiconductor die and the third semiconductor die. The second insulating encapsulant encapsulates the first chip package, the second semiconductor die, and the third semiconductor die.

Disclosed is a semiconductor package including: a redistribution substrate; at least one passive device in the redistribution substrate, the passive device including a first terminal and a second terminal; and a semiconductor chip on a top surface of the redistribution substrate, the semiconductor chip vertically overlapping at least a portion of the passive device, wherein the redistribution substrate includes: a dielectric layer in contact with a first lateral surface, a second lateral surface opposite to the first lateral surface, and a bottom surface of the passive device; a lower conductive pattern on the first terminal; a lower seed pattern provided between the first terminal and the conductive pattern, and directly connected to the first terminal; a first upper conductive pattern on the second terminal and a first upper seed pattern provided between the second terminal and the first upper conductive pattern, and directly connected to the second terminal.

Disclosed are packages and their fabrication methods. The package includes: a lower substrate with an upper pad; a lower chip on the lower substrate; a mold layer on the lower chip and the lower substrate; a post extending through the mold layer and provided on the upper pad around the lower chip, the post having a diameter less than a diameter of the upper pad; and an upper substrate on the post and the mold layer, the upper substrate including a lower pad having a diameter greater than the diameter of the post.

A semiconductor device and method for forming the semiconductor device is provided. The semiconductor device includes an integrated circuit having through vias adjacent to the integrated circuit die, wherein a molding compound is interposed between the integrated circuit die and the through vias. The through vias have a projection extending through a patterned layer, and the through vias may be offset from a surface of the patterned layer. The recess may be formed by selectively removing a seed layer used to form the through vias.

A semiconductor package includes a first redistribution structure having a first surface in which a first pad and a second pad are embedded and including a first redistribution layer thereon, and a vertical connection structure including a land layer and a pillar layer. The land layer is embedded in the first surface of the first redistribution structure, and a width of an upper surface of the land layer is narrower than a width of a lower surface of the pillar layer.

A semiconductor package includes a frame, a semiconductor chip, a through via, a connection pad, a lower redistribution layer on the bottom surfaces of the frame and the semiconductor chip, a connection terminal on the lower redistribution layer, an encapsulant covering the top surfaces of the frame and the semiconductor chip, and an upper redistribution layer on the encapsulant. The lower redistribution layer includes a lower insulating layer, a lower redistribution pattern, and an under-bump metal (UBM). The upper redistribution layer includes an upper insulating layer, an upper redistribution pattern, an upper via, and an upper connection pad. The lower insulating layer includes an inner insulating pattern surrounding the side surface of the UBM and an outer insulating pattern surrounding the side surface of the inner insulating pattern. The cyclization rate of the inner insulating pattern is higher than the cyclization rate of the outer insulating pattern.

A three-dimensional programmable interconnection system based on a multi-chip package includes: a programmable metal bump or pad at a bottom of the multi-chip package; a first programmable interconnect provided by an interposer of the multi-chip package; a second programmable interconnect provided by the interposer; and a switch provided by a first semiconductor chip of the multi-chip package, wherein the switch is configured to control connection between the first and second programmable interconnects, wherein the programmable metal bump or pad couples to a second semiconductor chip of the multi-chip package through the switch and the first and second programmable interconnects, wherein the first and second semiconductor chips are over the interposer.