A semiconductor package includes a semiconductor chip including a semiconductor substrate having an active layer, ground chip pads on the semiconductor substrate, and signal chip pads on the semiconductor substrate and a package substrate supporting the semiconductor chip, the package substrate including a substrate insulating layer, a plurality of signal line patterns extending in the substrate insulating layer and electrically connected to the signal chip pads, and a plurality of ground line patterns extending in the substrate insulating layer at a same level as a level of the plurality of signal line patterns and electrically connected to the ground chip pads. At least one of the plurality of ground line patterns extends between the plurality of signal line patterns.

A power amplifier comprises a first amplification stage having an input terminal receiving a radio frequency (RF) signal to be amplified and having a first coupling unit, a second amplification stage outputting an amplified radio frequency signal and having a second coupling unit and a third coupling unit providing RF feedback to the input terminal of the first amplification stage through an RF feedback path, the second coupling unit being coupled to the first coupling unit, and the third coupling unit being coupled to the first coupling unit.

An integrated circuit chip includes; a package substrate including a first signal ball, a first semiconductor chip on the package substrate, a second semiconductor chip on the first semiconductor chip, a first bump disposed between the package substrate and the first semiconductor chip and electrically connected to the first signal ball, and a second bump disposed between the first semiconductor chip and the second semiconductor chip and electrically connected to the first signal ball, wherein during a first mode, the first signal ball receives a signal from the first semiconductor chip through the first bump and receives a signal from the second semiconductor chip through the second bump.

A discrete power semiconductor package includes a semiconductor chip, a heatsink, a first lead, a second lead, and a clip. The heatsink is adjacent the semiconductor chip and draws heat away from the semiconductor chip. The clip binds the semiconductor chip to the heatsink and includes a chip linker, a first terminal, and a second terminal. The chip linker is atop the semiconductor chip. The first terminal connects to the first lead and the second terminal connects to the second lead.

An electronic package is provided in which an electronic structure is bonded onto a carrier structure via a plurality of conductive elements, where each of the conductive elements is connected to a single contact of the electronic structure via a plurality of conductive pillars. Therefore, when one of the conductive pillars fails, each of the conductive elements can still be electrically connected to the contact via the other of the conductive pillars to increase electrical conductivity.

A current sensor integrated circuit (IC) package is flip-chip bonded using a conductive film to connect the IC circuit bond pads to the lead frame. A conductive film is positioned between the die surface of a semiconductor die and at least one signal lead of the lead frame. The conductive film is conductive in a first direction between the die and the signal lead and nonconductive in other directions. The conductive film is further configured to control a gap height between the die and the lead frame to reduce die tilt, thus improving the sensitivity and performance consistency of the package.

A device comprises a substrate) of a first material with a surface, which is modified by depositing a bi-layer nanoparticle film. The film includes a nanoparticle layer of a second material on top of and in contact with surface, and a nanoparticle layer of a third material on top of and in contact with the nanoparticle layer of the second material. The nanoparticles of the third material adhere to the nanoparticles of the second material. The substrate region adjoining surface comprises an admixture of the second material in the first material. A fourth material contacts and chemically/mechanically bonds to the nanoparticle layer of the third material.

Methods/structures of joining package structures are described. Those methods/structures may include a die disposed on a surface of a substrate, an interconnect bridge embedded in the substrate, and at least one vertical interconnect structure disposed through a portion of the interconnect bridge, wherein the at least one vertical interconnect structure is electrically and physically coupled to the die.

A roll-to-roll sintering system for wide inorganic tape material may include a spool on which is wound a continuous tape material comprising a green tape material and a backing layer, a take-up reel, and a heating station including at least one furnace. The heating station is configured to receive an unwound length of the continuous tape. The heating station further includes a first curved section such that the continuous tape material is bent through a radius of curvature of 0.01 m to 13,000 m, and at least two rollers defining the first curved section over which the continuous tape material is bent. The heating station is controlled to provide at least a portion of the heating station with an air free atmosphere, that being at least one of vacuum, hydrogen, or helium.

An electronic device package and method of fabricating such a package includes a first and second components encapsulated in a volume of molding material. A surface of the first component is bonded to a surface of the second component. Upper and lower sets of redistribution lowers that include, respectively, first and second sets of conductive interconnects are formed on opposite sides of the molding material. A through-package interconnect passes through the volume of molding material and has ends that terminate, respectively, within the upper set of redistribution layers and within the lower set of redistribution layers.