A semiconductor device and method of manufacture are provided whereby an interposer and a first semiconductor device are placed onto a carrier substrate and encapsulated. The interposer comprises a first portion and conductive pillars extending away from the first portion. A redistribution layer located on a first side of the encapsulant electrically connects the conductive pillars to the first semiconductor device.

A semiconductor package includes a package substrate, a flip chip coupled to the package substrate, an interposer stacked on the flip chip and including a first terminal and a second terminal at an upper surface thereof, a bonding wire which connects the first terminal and the package substrate and a mold layer which covers the interposer, the flip chip and the bonding wire. The mold layer has a signal hole which exposes the second terminal, and at least one dummy hole spaced apart from the signal hole on an upper surface of the interposer.

A multi-die package on package includes a bottom package having a first device die and a second device die. A top package including a memory die is stacked on the bottom package.

A semiconductive device stack, includes a baseband processor die with an active surface and a backside surface, and a recess in the backside surface. A recess-seated device is disposed in the recess, and a through-silicon via in the baseband processor die couples the baseband processor die at the active surface to the recess-seated die at the recess. A processor die is disposed on the baseband processor die backside surface, and a memory die is disposed on the processor die. The several dice are coupled by through-silicon via groups.

A semiconductor device and method of manufacture are provided whereby an interposer and a first semiconductor device are placed onto a carrier substrate and encapsulated. The interposer comprises a first portion and conductive pillars extending away from the first portion. A redistribution layer located on a first side of the encapsulant electrically connects the conductive pillars to the first semiconductor device.

Disclosed herein are integrated circuit (IC) packages, antenna boards, antenna modules, and communication devices (e.g., for millimeter wave communications). For example, in some embodiments, an antenna module may include: a logic die; a radio frequency front-end (RFFE) die in electrical communication with the logic die; and an antenna patch, wherein the RFFE die is closer to the antenna patch than the logic die is to the antenna patch.

A semiconductive device stack, includes a baseband processor die with an active surface and a backside surface, and a recess in the backside surface. A recess-seated device is disposed in the recess, and a through-silicon via in the baseband processor die couples the baseband processor die at the active surface to the recess-seated die at the recess. A processor die is disposed on the baseband processor die backside surface, and a memory die is disposed on the processor die. The several dice are coupled by through-silicon via groups.

A semiconductor device and method of manufacture are provided whereby an interposer and a first semiconductor device are placed onto a carrier substrate and encapsulated. The interposer comprises a first portion and conductive pillars extending away from the first portion. A redistribution layer located on a first side of the encapsulant electrically connects the conductive pillars to the first semiconductor device.

A semiconductor package with clock sharing, which is suitable for an electronic system having low power consumption characteristics, is provided. The semiconductor package includes a lower package including a lower package substrate and a memory controller mounted on the lower package substrate, an upper package stacked on the lower package and including an upper package substrate and a memory device mounted on the upper package substrate, and a plurality of vertical interconnections electrically connecting the lower package to the upper package. The semiconductor package is configured to cause the memory controller to output a first data clock signal used for a channel that is an independent data interface between the memory controller and the memory device, branch the first data clock signal, and provide the branched first data clock signal to the memory device.

A semiconductor device is provided. The semiconductor device includes a first hard macro; a second hard macro spaced apart from the first hard macro in a first direction by a first distance; a head cell disposed in a standard cell area between the first hard macro and the second hard macro, the head cell being configured to perform power gating of a power supply voltage provided to one from among the first hard macro and the second hard macro; a plurality of first ending cells disposed in the standard cell area adjacent to the first hard macro; and a plurality of second ending cells disposed in the standard cell area adjacent to the second hard macro, the head cell not overlapping the plurality of first ending cells and the plurality of second ending cells.