Leadless power amplifier (PA) packages and methods for fabricating leadless PA packages having topside terminations are disclosed. In embodiments, the method includes providing electrically-conductive pillar supports and a base flange. At least a first radio frequency (RF) power die is attached to a die mount surface of the base flange and electrically interconnected with the pillar supports. Pillar contacts are further provided, with the pillar contacts electrically coupled to the pillar supports and projecting therefrom in a package height direction. The first RF power die is enclosed in a package body, which at least partially defines a package topside surface opposite a lower surface of the base flange. Topside input/out terminals are formed, which are accessible from the package topside surface and which are electrically interconnected with the first RF power die through the pillar contacts and the pillar supports.

The present disclosure relates to a semiconductor package device including a stacked antenna structure with a high-k laminated dielectric layer separating antenna and ground planes, and a method of manufacturing the structure. A semiconductor die is laterally encapsulated within an insulating structure comprising a first redistributions structure. A second redistribution structure is disposed over and electrically coupled to the first redistribution structure and the die. The second redistribution structure includes the stacked antenna structure which includes first and second conductive planes separated by a high dielectric constant laminated dielectric structure. The first conductive plane includes openings and the second conductive plane is configured to transmit and receive electromagnetic waves through the openings in the first conductive plane.

A radio frequency (RF) chip package includes: an RF die; a first peripheral circuit chip; a second peripheral circuit chip; a substrate having a -shaped step formed on a portion thereof so that the RF die is mounted on top of the step of the substrate and the first peripheral circuit chip and the second peripheral circuit chip are mounted on top of the substrate where no step is formed; a first mutual inductance controller for controlling the dimension of the mutual inductance between the first peripheral circuit chip and the RF die; and a second mutual inductance controller for controlling the dimension of the mutual inductance between the second peripheral circuit chip and the RF die.

A device includes a semiconductor die including a transistor. The transistor includes a plurality of parallel transistor elements. Each transistor element includes a drain region, a source region, and a gate region. The semiconductor die includes a first temperature sensor between a first transistor element in the plurality of transistor elements and a second transistor element in the plurality of transistor elements. The first temperature sensor is configured to generate a first output signal having a magnitude that is proportional to a temperature of the first temperature sensor.

Antenna systems with millimeter wave diplexing using antenna feeds are provided. In certain embodiments, a mobile device includes a front-end system including a first radio frequency circuit configured to output a first radio frequency signal of a first carrier frequency, and a second radio frequency circuit configured to output a second radio frequency signal of a second carrier frequency. The mobile device further includes a patch antenna including a first signal feed configured to receive the first radio frequency and a second signal feed configured to receive the second signal feed, the first signal feed providing a high impedance at the second carrier frequency and the second signal feed providing a high impedance at the first carrier frequency.

A device that includes a metal submount; a first transistor die arranged on said metal submount; a second transistor die arranged on said metal submount; a set of primary interconnects; and a set of secondary interconnects. Additionally, the set of primary interconnects and the set of secondary interconnects are configured to provide RF signal coupling between the first transistor die and the second transistor die by electromagnetic coupling.

Compute complexes, base dies, and methods related to leveraging reticle stitching for improved device interconnects are discussed. A base die includes first and second regions having device layers, lower level metallization layers, and through vias fabricated using the same reticles. In the first region, a first subset of the through vias are contacted by higher metallization layers and, in the second region, a second distinct subset of the through vias are contacted by higher metallization layers such that the first and second metallization layers provide unique routing through vias having shared layouts and relative locations in the first and second regions.

Embodiments may relate to a radio frequency (RF) multi-chip module that includes a first RF die and a second RF die. The first and second RF dies may be coupled with a package substrate at an inactive side of the respective dies. A bridge may be coupled with an active side of the first and second RF dies die such that the first and second RF dies are communicatively coupled through the bridge, and such that the first and second RF dies are at least partially between the package substrate and the bridge. Other embodiments may be described or claimed.

An RF transistor package includes a metal submount; a transistor die mounted to the metal submount; and a surface mount IPD component mounted to the metal submount. The surface mount IPD component includes a dielectric substrate that includes a top surface and a bottom surface and at least a first pad and a second pad arranged on a top surface of the surface mount IPD component; at least one surface mount device includes a first terminal and a second terminal, the first terminal of the surface mount device mounted to the first pad and the second terminal mounted to the second pad; at least one of the first terminal and the second terminal being configured to be isolated from the metal submount by the dielectric substrate; and at least one wire bond bonded to the at least one of the first pad and the second pad.

A semiconductor device includes a base, a matching circuit including a substrate, a ground layer, and a signal line, wherein a width of the signal line on a first end side of the substrate is smaller than a width of the substrate and larger than that of the signal line on a second end side, and a distance between the ground layer and the signal line on the first end side is larger than a distance therebetween on the second end side, a semiconductor element electrically connected to the signal line on the first end side of the matching circuit by first bonding wires, a frame body, a feedthrough having a lead, and second bonding wires electrically connected to the lead and the signal line on the second end side, wherein the first bonding wires are arranged in parallel, and the second bonding wires are arranged in parallel.