Disclosed herein are antenna boards, integrated circuit (IC) packages, antenna modules, and communication devices. For example, in some embodiments, an antenna module may include: an IC package having a die and a package substrate, and the package substrate has a recess therein; and an antenna patch, coupled to the package substrate, such that the antenna patch is over or at least partially in the recess.

An electronic component module (100) includes a module board (10) having electronic components (40) mounted on at least one of a first surface (front surface) (12) and a second surface (back surface) (14), mold portions (22 and 23), and a shield (32). The mold portions (22 and 23) cover the mounted electronic components (40). The shield (32) covers at least a part of the mold portions (22 and 23) and the side surfaces of the module board (10). Protrusions (15) protruding from the side surfaces are formed on the module board (10). The shield (32) is separated by the protrusions (15).

Disclosed is an antenna module including a first printed circuit board (PCB) including a first surface facing a first direction and a second surface facing a second direction opposite the first direction, a second PCB including a third surface facing the first direction spaced from the first PCB and a fourth surface facing the second direction spaced from the first surface, a radio frequency integrated circuit (RFIC) disposed on the first surface, and a connection member comprising a conductive material connecting the first surface to the fourth surface. The at least one first conductive pattern is connected to the RFIC. The at least one third conductive pattern is connected to the RFIC via the connection member. The at least one first conductive pattern and the at least one third conductive pattern at least partially overlap with each other at least partly, when viewed from above the second surface.

A component carrier for carrying at least one electronic component includes (a) a plurality of electrically conductive layers; (b) a plurality of electrically insulating layers; and (c) a thermoplastic structure. The electrically conductive layers, the electrically insulating layers, and the thermoplastic structure form a laminate. Further, a method for manufacturing such a component carrier and an electronic apparatus including such a component carrier are provided.

A method includes encapsulating a device in an encapsulating material, planarizing the encapsulating material and the device, and forming a conductive feature over the encapsulating material and the device. The formation of the conductive feature includes depositing a first conductive material to from a first seed layer, depositing a second conductive material different from the first conductive material over the first seed layer to form a second seed layer, plating a metal region over the second seed layer, performing a first etching on the second seed layer, performing a second etching on the first seed layer, and after the first seed layer is etched, performing a third etching on the second seed layer and the metal region.

A semiconductor package includes a redistribution substrate including a conductive structure having a lower conductive pattern and a redistribution structure electrically connected to the lower conductive pattern, on the lower conductive pattern, an insulating structure covering at least a side surface of the redistribution structure, and a protective layer between the lower conductive pattern and the insulating structure, a semiconductor chip on the redistribution substrate, and a lower connection pattern below the redistribution substrate and electrically connected to the lower conductive pattern. The protective layer includes a first portion in contact with at least a portion of an upper surface of the lower conductive pattern, and a second portion in contact with at least a portion of a side surface of the lower conductive pattern.

A computing chip can include one or more voltage regulators to decrease a standard voltage, such as twelve volts, to a relatively low operating voltage of its processing cores, typically around one volt. Because the power consumed by the cores can be substantial, such as three hundred watts or more, it is desirable to locate the voltage regulators as close as possible to the cores, to reduce the distances that relatively large currents have to travel in the chip circuitry. The voltage regulators can be embedded within the package, such as in a layered structure, in a layer that electrically connects to the cores. While the cores are typically manufactured using the smallest possible lithographic features, the voltage regulators are less demanding and can instead use relatively large lithographic features, which can be formed using relatively old technology, and can therefore be relatively inexpensive.

A device that includes a substrate and a power amplifier coupled to the substrate. The substrate includes at least one dielectric layer, a plurality of interconnects, and a capacitor configured to operate as an output match element, where the capacitor is defined by a plurality of capacitor interconnects. The power amplifier is coupled to the capacitor. The capacitor is configured to operate as an output match element for the power amplifier. The substrate includes an inductor coupled to the capacitor, where the inductor is defined by at least one inductor interconnect. The capacitor and the inductor are configured to operate as a resonant trap or an output match element.

An electronics package is disclosed. The electronics package includes a first radio frequency (RF) substrate layer, a second RF substrate layer, and a plurality of conductive layers disposed adjacent to at least one of the first RF substrate layer and the second RF substrate layer and including an inner conductive layer disposed between and adjacent to both the first RF substrate layer and the second RF substrate layer. The inner conductive layer bonds the first RF substrate layer to the second RF substrate layer. The electronics package also includes a plurality of conductive interconnects extending through the first RF substrate layer and the second RF substrate layer and electrically coupled between at least two of the plurality of conductive layers.

A direct bonded heterogeneous integration (DBHi) device includes a substrate including a trench formed in a top surface of the substrate. The DBHi device further includes a first chip coupled to the substrate on a first side of the trench by a plurality of first interconnects. The DBHi device further includes a second chip coupled to the substrate on a second side of the trench by a plurality of second interconnects. The second side of the trench is arranged opposite the first side of the trench. The DBHi device further includes a bridge coupled to the first chip and to the second chip by a plurality of third interconnects such that the bridge is suspended in the trench. The DBHi device further includes a non-conductive paste material surrounding the plurality of third interconnects to further couple the bridge to the first chip and to the second chip.