A semiconductor package includes a package substrate having a top surface and a bottom surface, and a stiffener ring mounted on the top surface of the package substrate. The stiffener ring includes a reinforcement rib that is coplanar with the stiffener ring on the top surface of the package substrate. At least two compartments are defined by the stiffener ring and the reinforcement rib. At least two individual chip packages are mounted on chip mounting regions within the at least two compartments, respectively, thereby constituting a package array on the package substrate.

A device assembly includes a functional substrate having one or more electronic components formed there. The functional substrate has a cavity extending from a first surface toward a second surface of the functional substrate at a location that lacks the electronic components. The device assembly further includes a semiconductor die placed within the cavity with a pad surface of the semiconductor die being opposite to a bottom of the cavity. The functional substrate may be formed utilizing a first fabrication technology and the semiconductor die may be formed utilizing a second fabrication technology that differs from the first fabrication technology.

A method for fabricating a dual redistribution layer (RDL) interposer structure is provided. The method includes etching a semiconductor substrate to expose natural crystallographic planes to form trenches. The method also includes depositing conductive material within the trenches of the etched semiconductor substrate to form vias for an interposer structure. The method includes placing back end of line (BEOL) inter-chip wiring on a top side of the interposer structure using a first RDL. The method includes exposing the vias on a back side of the interposer structure. The method further includes forming power RDLs on a back side of the interposer structure using conductive lines in a dielectric layer.

The present disclosure relates to a semiconductor module. The semiconductor module includes an excitable element located on a first side of a substrate. A first ground structure is disposed between the first side of the substrate and the excitable element. The first ground structure includes a conductive via extending through the substrate and an interconnect disposed over a topmost surface of the conductive via facing away from the substrate. A second ground structure is located on a second side of the substrate, opposing the first side, and electrically coupled to the first ground structure.

Package on package (PoP) devices and methods of packaging semiconductor dies are disclosed. A PoP device includes a first packaged die and a second packaged die coupled to the first packaged die. Metal stud bumps are disposed between the first packaged die and the second packaged die. The metal stud bumps include a bump region and a tail region coupled to the bump region. The metal stud bumps are embedded in solder joints.

Certain aspects of the present disclosure provide techniques for relate to electronic devices that are configured to implement multi-rank high bandwidth memory (HBM) memory. In one aspect, an electronic device includes a chip that includes an interface circuit. The interface circuit is connected to first exterior pads. The first exterior pads have a first number of first data input/output exterior pads and a second number of clock enable output exterior pads. The first number is a first integer multiple of a number of data signals per channel of high bandwidth memory (HBM), and the second number is a second integer multiple of a number of clock enable signals per channel of the HBM. The second integer multiple is greater than the first integer multiple.

A semiconductor device structure and a method for manufacturing a semiconductor device. As a non-limiting example, various aspects of this disclosure provide a method for manufacturing a semiconductor device that comprises ordering and performing processing steps in a manner that prevents warpage deformation from occurring to a wafer and/or die due to mismatching thermal coefficients.

An assembly structure includes a core-computing section and a sub-computing section. The core-computing section has a first surface and a second surface opposite to the first surface. The core-computing section includes at least one conductive via electrically connecting the first surface and the second surface. The sub-computing section has a first surface stacked on the first surface of the core-computing section and a second surface opposite to the first surface. The sub-computing section includes at least one conductive via electrically connecting the first surface and the second surface. The assembly structure includes a first signal transmission path and a second signal transmission path. The first signal transmission path is between the at least one conductive via of the sub-computing section and the at least one conductive via of the core-computing section. The second signal transmission path is between the second surface of the sub-computing section and the at least one conductive via of the sub-computing section.

An embodiment is a structure comprising a substrate, a first die, and a second die. The substrate has a first surface. The first die is attached to the first surface of the substrate by first electrical connectors. The second die is attached to the first surface of the substrate by second electrical connectors. A size of one of the second electrical connectors is smaller than a size of one of the first electrical connectors.

An interposer substrate is manufactured with a scribe line between adjacent regions. In an embodiment a separate exposure reticle is utilized to pattern the scribe line. The exposure reticle to pattern the scribe line will create an exposure region which overlaps and overhangs the exposure regions utilized to form adjacent regions.