Embodiments disclosed herein include electronic packages. In an embodiment, the electronic package comprises, a package substrate, an interposer on the package substrate, a first die cube and a second die cube on the interposer, wherein the interposer includes conductive traces for electrically coupling the first die cube to the second die cube, a die on the package substrate, and an embedded multi-die interconnect bridge (EMIB) in the package substrate, wherein the EMIB electrically couples the interposer to the die.

A power module includes a base plate, first, second, and third semiconductor chips. At least one of a third edge or fourth edge of the first semiconductor chip is disposed adjacent to a side end of the base plate. Among a half of a distance from a first edge of the first semiconductor chip to one edge of the second semiconductor chip, a half of a distance from a second edge of the first semiconductor chip to one edge of the third semiconductor chip, and a distance from the third edge or fourth edge of the first semiconductor chip disposed adjacent to the side end of the base plate to the side end of the base plate, a length of a solder fillet formed on the edge of the first semiconductor chip at the shortest distance is formed in the shortest length.

Disclosed is a semiconductor package structure comprising a body, a plurality of first-layer, second-layer, third-layer and fourth-layer electrical contacts, wherein the first-layer, the second-layer, the third-layer and the fourth-layer electrical contacts are arranged sequentially from outside to inside on a bottom surface of the body in a matrix manner. Adjacent first-layer electrical contacts have two different spacings therein, and adjacent third-layer electrical contacts have the two different spacings therein.

A semiconductor package comprises a first die having a central region and a peripheral region that surrounds the central region; a plurality of through electrodes that penetrate the first die; a plurality of first pads at a top surface of the first die and coupled to the through electrodes; a second die on the first die; a plurality of second pads at a bottom surface of the second die, the bottom surface of the second die facing the top surface of the first die; a plurality of connection terminals that connect the first pads to the second pads; and a dielectric layer that fills a space between the first die and the second die and surrounds the connection terminals. A first width of each of the first pads in the central region may be greater than a second width of each of the first pads in the peripheral region. Each of the connection terminals may include a convex portion at a lateral surface thereof, which protrudes beyond a lateral surface of a respective first pad and a lateral surface of a respective second pad. The convex portion may protrude in a direction away from a center of the first die. Protruding distances of the convex portions may increase in a direction from the center of the first die toward an outside of the first die.

In some examples, an electronic package and methods for forming the electronic package are described. The electronic package can be formed by disposing an interposer on a surface of a substrate having a first pitch wiring density. The interposer can have a second pitch wiring density different from the first pitch wiring density. A layer of non-conductive film can be situated between the interposer and the surface of the substrate. A planarization process can be performed on a surface of the substrate. A solder resist patterning can be performed on the planarized surface the substrate. A solder reflow and coining process can be performed to form a layer of solder bumps on top of the planarized surface of the substrate. The interposer can provide bridge connection between at least two die disposed above the substrate. Solder bumps under the interposer electrically connect the substrate and the interposer.

A structure is provided that reduces the stress generated in a semiconductor device package during cooling subsequent to solder reflow operations for coupling semiconductor devices to a printed circuit board (PCB). Stress reduction is provided by coupling solder lands to metal-layer structures using traces on the PCB that are oriented approximately perpendicular to lines from an expansion neutral point associated with the package. In many cases, especially where the distribution of solder lands of the semiconductor device package are uniform, the expansion neutral point is in the center of the semiconductor device package. PCB traces having such an orientation experience reduced stress due to thermal-induced expansion and contraction as compared to traces having an orientation along a line to the expansion neutral point.

A semiconductor package may include vertically-stacked semiconductor chips and first, second, and third connection terminals connecting the semiconductor chips to each other. Each of the semiconductor chips may include a semiconductor substrate, an interconnection layer on the semiconductor substrate, penetration electrodes connected to the interconnection layer through the semiconductor substrate, and first, second, and third groups on the interconnection layer. The interconnection layer may include an insulating layer and first and second metal layers in the insulating layer. The first and second groups may be in contact with the second metal layer, and the third group may be spaced apart from the second metal layer. Each of the first and third groups may include pads connected to a corresponding one of the first and third connection terminals in a many-to-one manner. The second group may include pads connected to the second connection terminal in a one-to-one manner.

A semiconductor package is provided. The semiconductor package includes: a first stack including a first semiconductor substrate; a through via that penetrates the first semiconductor substrate in a first direction; a second stack that includes a second face facing a first face of the first stack, on the first stack; a first pad that is in contact with the through via, on the first face of the first stack; a second pad including a concave inner side face that defines an insertion recess, the second pad located on the second face of the second stack; and a bump that connects the first pad and the second pad, wherein the bump includes a first upper bump on the first pad, and a first lower bump between the first upper bump and the first pad.

Embodiments disclosed herein include electronic packages. In an embodiment, the electronic package comprises, a package substrate, an interposer on the package substrate, a first die cube and a second die cube on the interposer, wherein the interposer includes conductive traces for electrically coupling the first die cube to the second die cube, a die on the package substrate, and an embedded multi-die interconnect bridge (EMIB) in the package substrate, wherein the EMIB electrically couples the interposer to the die.

A processor-implemented method and integrated circuit package are provided. According to an implementation, a method of producing a chip package includes de-populating solder balls at selected locations in a fine pitch package, and providing test pads at the de-populated solder ball locations. In an example implementation, the method comprises receiving and modifying a package design. In an implementation, a row of test pads in an integrated circuit package is provided in a plurality of concentric annular rows, the row of test pads being adjacent an outer row of via-connected solder balls and adjacent an inner row of via-connected solder balls. In an implementation, test pads are located on a PCB-facing surface of the package at a subset of locations opposing at least one via position on a package-facing surface of the PCB. The test pads maintain a large number of signal pins and do not interfere with the via.