Antenna modules employing three-dimensional (3D) build-up on mold package to support efficient integration of radio-frequency (RF) circuitry, and related fabrication methods. The antenna module includes a RF transceiver whose circuitry is split over multiple semiconductor dies (“dies”) so different semiconductor devices can be formed in different semiconductor structures. The antenna module is provided as a 3D build-up on mold package to reduce lengths of die-to-die (D2D) interconnections between circuits in different dies. First and second die packages that include respective first and second dies encapsulated in respective first and second mold layers are coupled to each other in a vertical direction in a 3D stacked arrangement with active faces of the first and second dies facing each other to provide a reduced distance between the active faces of the first and second dies. An antenna is stacked on the second die package to provide an antenna(s) for the antenna module.

Certain aspects of the present disclosure generally relate to an integrated circuit assembly. One example integrated circuit assembly generally includes a first reconstituted assembly, a second reconstituted assembly, and a third reconstituted assembly. The first reconstituted assembly comprises at least one passive component and a first bonding layer. The second reconstituted assembly is disposed above the first reconstituted assembly and comprises one or more first semiconductor dies, a second bonding layer bonded to the first bonding layer of the first reconstituted assembly, and a third bonding layer. The third reconstituted assembly is disposed above the second reconstituted assembly and comprises one or more second semiconductor dies and a fourth bonding layer bonded to the third bonding layer of the second reconstituted assembly.

A semiconductor device package includes a first substrate having an electrical circuit, semiconductor dies stacked one on top of the other, and bond wires electrically connected one to another. The bond wires electrically couple the semiconductor dies to one another and to the electrical circuit. There is a first bond wire having a first portion connected to a first semiconductor die, a second portion connected to a second semiconductor die, and an intermediate portion between the first portion and second portion. The semiconductor device package further includes a molding compound encapsulating the semiconductor dies, and the first and second portions of the first bond wire. The intermediate portion of the first bond wire is exposed along a top planar surface of the molding compound. The semiconductor device package may be used for coupling one or more other semiconductor device packages thereto via the exposed intermediate portion.

In an embodiment, a structure includes: a first integrated circuit die including first die connectors; a first dielectric layer on the first die connectors; first conductive vias extending through the first dielectric layer, the first conductive vias connected to a first subset of the first die connectors; a second integrated circuit die bonded to a second subset of the first die connectors with first reflowable connectors; a first encapsulant surrounding the second integrated circuit die and the first conductive vias, the first encapsulant and the first integrated circuit die being laterally coterminous; second conductive vias adjacent the first integrated circuit die; a second encapsulant surrounding the second conductive vias, the first encapsulant, and the first integrated circuit die; and a first redistribution structure including first redistribution lines, the first redistribution lines connected to the first conductive vias and the second conductive vias.

A package includes a first and a second package component. The first package component includes a first metal trace and a second metal trace at the surface of the first package component. The second metal trace is parallel to the first metal trace. The second metal trace includes a narrow metal trace portion having a first width, and a wide metal trace portion having a second width greater than the first width connected to the narrow metal trace portion. The second package component is over the first package component. The second package component includes a metal bump overlapping a portion of the first metal trace, and a conductive connection bonding the metal bump to the first metal trace. The conductive connection contacts a top surface and sidewalls of the first metal trace. The metal bump is neighboring the narrow metal trace portion.

A package method of modular stacked semiconductor package is disclosed. A carrier and a plurality of the chip modules are provided. A plurality of redistribution layers are respectively formed in device areas of the carrier. The chip modules are stacked on the corresponding device areas of the carrier and are electrically connected to each other. A molding compound is formed on the redistribution layers on the carrier to encapsulate the chip modules. The carrier is removed to expose the redistribution layers. A plurality of solder balls are formed on the exposed redistribution layers. The molding compound is cut along adjacent edges of the device areas to form a plurality of modular stacked semiconductor packages. Since the chip modules are previously fabricated, connecting quality among the stacked chip modules is enhanced and is not affected by positioning error.

An electronic package is provided, in which at least one first electronic component is arranged on one surface of a circuit structure with circuit layers and a plurality of second electronic components are arranged on the other surface. The first electronic component can electrically bridge two of the plurality of second electronic components via the circuit layers to replace part of the circuit layers of the circuit structure, so that the circuit layers of the circuit structure can maintain a larger wiring specification and reduce the number of circuit layers, thereby improving the process yield.

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.

A lower semiconductor package of a package-on-package type semiconductor package includes: a package substrate; a semiconductor chip mounted on the package substrate; a chip connecting terminal disposed between the semiconductor chip and the package substrate and configured to connect the semiconductor chip to the package substrate; conductive pillars arranged on the package substrate to at least partially surround the semiconductor chip; and a dam structure configured to cover the conductive pillars on the package substrate and having a first opening at least partially surrounding the semiconductor chip.

A semiconductor package includes a lower redistribution layer having a plurality of lower ball pads forming a plurality of lower ball pad groups, a semiconductor chip on the lower redistribution layer, an expanded layer surrounding the semiconductor chip on the lower redistribution layer, and an upper redistribution layer on the semiconductor chip and the expanded layer and having a plurality of upper ball pads forming a plurality of upper ball pad groups. The number of the plurality of upper ball pad groups may be the same as the number of the of the plurality lower ball pad groups. Each of the upper ball pads in one of the plurality of upper ball pad groups, from among the plurality of upper ball pads, may be a dummy ball pad.