A device includes a ground plane electrically connected to a proximal end of at least one conductive pillar and an antenna pad substantially parallel to the ground plane, wherein the antenna pad is separated from a distal end of the at least one conductive pillar by a dielectric pad having a first dielectric constant, wherein the ground plane, the at least one conductive pillar, and the dielectric pad surround an antenna cavity filled with a dielectric fill material having a second dielectric constant different from the first dielectric constant.

A semiconductor apparatus includes an interconnect substrate which includes an antenna module region in which an antenna and a semiconductor integrated circuit electrically connected to the antenna are disposed, and at least one evaluation region situated next to the antenna module region and used to evaluate characteristics of the antenna, wherein the at least one evaluation region has at least one slit formed therein such that the slit includes at least a portion, situated opposite the antenna, of a boundary line that separates the antenna module region and the evaluation region from each other.

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.

An integrated circuit, IC, comprising one or more DC blocking modules connected to a respective input/output, IO, pin of the IC, each DC blocking module comprising: a capacitor having a first terminal connected to the respective IO pin and a second terminal connected to a node of the circuitry of the IC; and an electrostatic discharge, ESD, protection circuit connected in parallel to the capacitor, the ESD protection circuit comprising: a conduction path connected between the first terminal of the capacitor and the second terminal of the capacitor; and a control terminal configured to receive a control signal to switch the ESD protection circuit between: an operational mode in which the conduction path is in a non-conducting state and provides ESD protection to the capacitor; and a test mode in which the conduction path is in a conducting state and short circuits the capacitor.

A semiconductor package and a manufacturing method thereof are provided. The semiconductor package includes: patch antennas, encapsulated by a first encapsulant; a device die, vertically spaced apart from the patch antennas, and electrically coupled to the patch antennas; and at least one redistribution structure, disposed between the patch antennas and the device die, and including electromagnetic bandgap (EBG) structures laterally surrounding each of the patch antennas.

The present disclosure relates to an electronic circuit comprising a semiconductor substrate, radiofrequency switches corresponding to MOS transistors comprising doped semiconductor regions in the substrate, at least two metallization levels covering the substrate, each metallization level comprising a stack of insulating layers, conductive pillars topped by metallic tracks, at least two connection elements each connecting one of the doped semiconductor regions and formed by conductive pillars and conductive tracks of each metallization level. The electronic circuit further comprises, between the two connection elements, a trench crossing completely the stack of insulating layers of one metallization level and further crossing partially the stack of insulating layers of the metallization level the closest to the substrate, and a heat dissipation device adapted for dissipating heat out of the trench.

This application provides a chip apparatus, including a die, a first bond pad, a second bond pad, and a first solder pad. The first bond pad and the second bond pad are disposed on an upper surface of the die. A first power module and a second power module are disposed in the die. The first power module is coupled to the first bond pad. The second power module is coupled to the second bond pad. The first solder pad is separately coupled to an external power supply of the chip apparatus, the first bond pad, and the second bond pad. According to the foregoing technical solution, isolation between different power modules is improved, and noise transmitted on a power supply path can be better filtered out. This improves power supply noise performance of the chip apparatus.

An SIP module includes a plurality of electrical components mounted to an interconnect substrate. The electrical components and interconnect substrate are covered by an encapsulant. A conductive post is formed through the encapsulant. A plurality of openings is formed in the encapsulant by laser in a form of a circuit pattern. A conductive material is deposited over a surface of the encapsulant and into the openings to form an electrical circuit pattern. A portion of the conductive material is removed by a grinder to expose the electrical circuit pattern. The grinding operation planarizes the surface of the encapsulant and the electrical circuit pattern. The electrical circuit pattern can be a trace, contact pad, RDL, or other interconnect structure. The electrical circuit pattern can also be a shielding layer or antenna. An electrical component is disposed over the SIP module and electrical circuit pattern.

An electronic package is provided, in which a ground layer is arranged on one side of an insulator, and a first antenna portion and a second antenna portion embedded in the insulator are vertically disposed on the ground layer, where a gap is formed between the first antenna portion and the second antenna portion, such that the first antenna portion and the second antenna portion are electrically matched with each other, and the ground layer is electrically connected to the second antenna portion but free from being electrically connected to the first antenna portion.