Disclosed is a semiconductor package comprising a redistribution substrate and a semiconductor chip on the redistribution substrate. The redistribution substrate includes a plurality of first conductive patterns including a pair of first signal patterns that are adjacent to each other, and a plurality of second conductive patterns on surfaces of the first conductive patterns and coupled to the first conductive patterns. The second conductive patterns include a ground pattern insulated from the pair of first signal patterns. The ground pattern has an opening that penetrates the ground pattern. When viewed in plan, the pair of first signal patterns overlap the opening.

This invention provides opportunity for diamond and bi-wafer microstructures to be implemented in advanced ICs and advanced IC packages to form a new breed of ICs and SiPs that go beyond the limitations of silicon at the forefront of IC advancement due primarily to diamond's extreme heat dissipating ability. Establishing the diamond and bi-wafer microstructure capabilities and implementing them in advanced ICs and advanced IC packages gives IC and package architects and designers an extra degree of design freedom in achieving extreme IC performance, particularly when thermal management presents a challenge. Diamond's extreme heat spreading ability can be used to dissipate hotspots in processors and other high-power chips such as GaN HEMT, resulting in performance and reliability enhancement for IC and package applications covering HPC, AI, photonics, 5G RF/mmWave, power and IoT, and at the system level propelling the migration from traditional computing to near-memory computing and in-memory computing.

A package structure including a semiconductor die, a redistribution layer, a plurality of antenna patterns, a die attach film, and an insulating encapsulant is provided. The semiconductor die have an active surface and a backside surface opposite to the active surface. The redistribution layer is located on the active surface of the semiconductor die and electrically connected to the semiconductor die. The antenna patterns are located over the backside surface of the semiconductor die. The die attach film is located in between the semiconductor die and the antenna patterns, wherein the die attach film includes a plurality of fillers, and an average height of the die attach film is substantially equal to an average diameter of the plurality of fillers. The insulating encapsulant is located in between the redistribution layer and the antenna patterns, wherein the insulating encapsulant encapsulates the semiconductor die and the die attach film.

The present disclosure is directed to conductive structures that may be utilized in a radio-frequency (RF) switch. The embodiments of the conductive structures of the present disclosure are formed to balance the on resistance (R.sub.on) and the off capacitance (C.sub.off) such that the R.sub.on.Math.C.sub.off value is optimized such that the conductive structures are relatively efficient as compared to conventional conductive structures within conventional RF switches. For example, the conductive structures include various metallization layers that are stacked on each other and spaced apart in a selected manner to balance the R.sub.on and the C.sub.off as to optimize the R.sub.on.Math.C.sub.off figure of merit as a lower R.sub.on.Math.C.sub.off is preferred.

The present disclosure is directed to conductive structures that may be utilized in a radio-frequency (RF) switch. The embodiments of the conductive structures of the present disclosure are formed to balance the on resistance (R.sub.on) and the off capacitance (C.sub.off) such that the R.sub.on.Math.C.sub.off value is optimized such that the conductive structures are relatively efficient as compared to conventional conductive structures within conventional RF switches. For example, the conductive structures include various metallization layers that are stacked on each other and spaced apart in a selected manner to balance the R.sub.on and the C.sub.off as to optimize the R.sub.on.Math.C.sub.off figure of merit as a lower R.sub.on.Math.C.sub.off is preferred.

A semiconductor device includes a receiving terminal for receiving a signal transmitted through a signal transmission line, a reference plane voltage terminal connected to a refence plane as a refence for the signal on the signal transmission line and a voltage generating circuit configured to generate a refence plane voltage to be supplied to the reference plane voltage terminal based on the signal received by the receiving terminal.

Provided is a method for forming a partial shielding for an electronic assembly, comprising: providing an electronic assembly mounted on a mother board, wherein the electronic assembly comprises a substrate, and at least one electronic component and a conductive pattern mounted on a top surface of the substrate; disposing a mask onto the substrate to cover the at least one electronic component; forming an encapsulant layer on the mother board to encapsulate at least the electronic assembly; forming a trench through the encapsulant layer to expose at least a portion of the conductive pattern and at least a portion of lateral surfaces of the mask; forming a shielding layer on the mother board to cover the encapsulant layer and fill in the trench; and detaching the mask from the mother board.

A radio frequency (RF) bridge that may include a body having an interfacing surface and a bonding surface extending from the interfacing surface. RF bridge may also include an interconnect operably engaged with the body. The interconnect may have at least one electrical connection positioned at the interfacing surface and at least another electrical connection positioned at the interfacing surface adjacent with the at least one electrical connection. The interconnect extends curvilinearly between the at least one electrical connection and the at least another electrical connection creating a curvilinear signal path.

A radio frequency (RF) bridge that may include a body having an interfacing surface and a bonding surface extending from the interfacing surface. RF bridge may also include an interconnect operably engaged with the body. The interconnect may have at least one electrical connection positioned at the interfacing surface and at least another electrical connection positioned at the interfacing surface adjacent with the at least one electrical connection. The interconnect extends curvilinearly between the at least one electrical connection and the at least another electrical connection creating a curvilinear signal path.

The present disclosure provides an electronic device. The electronic device includes a circuit structure, an interconnection structure disposed over the circuit structure, and an antenna element disposed over the interconnection structure. The antenna element defines a first recess having a sidewall, and the sidewall of the first recess of the antenna element is configured to feed a signal to the antenna element and is electrically connected to the interconnection structure.