A semiconductor device includes a semiconductor chip with bonding pads, the bonding pads being arranged along one side of an element forming surface of the semiconductor chip, a lead frame including first and second internal leads arranged such that tips thereof correspond to some of the bonding pads of the semiconductor chip, and first and second bonding wires by which the first internal leads and the some of the bonding pads are bonded to each other. The semiconductor device further includes a hanging pin section provided on the element non-forming surface of the semiconductor chip, and a sealing member with which the semiconductor chip is sealed including the hanging pin section and a bonding section between the first and second internal leads and the first and second bonding wires.

A semiconductor package includes a substrate including an antenna; a heating element disposed on a first surface of the substrate and connected to the antenna; a heat radiating part coupled to the heating element; and a signal transfer part disposed on the first surface of the substrate and configured to electrically connect the substrate to a main substrate. The heat radiating part may include a heat transfer part connected to the heating element and heat radiating terminals connecting the heat transfer part and the main substrate to each other.

Multi-chip systems and structures for modular scaling are described. In some embodiments an interfacing bar is utilized to couple adjacent chips. For example, a communication bar may utilized to coupled logic chips, and memory bar may be utilized to couple multiple memory chips to a logic chip.

A high-frequency module includes a circuit board including wiring patterns, a resin on an active element mounted on the circuit board and a side of the circuit board and sealing the active element, and connection conductors penetrating the resin from a surface of the resin and provided on a top surface of the active element. The active element includes a first connection electrode on a surface facing the circuit board, and a second connection electrode on a top surface opposite to the surface facing the circuit board. The first connection electrode is connected to a wiring pattern on the circuit board, and the second connection electrode is connected to the connection conductor and an outer electrode and is not connected to the wiring pattern.

A memory card includes a memory card body dimensioned to house at least one integrated circuit die package. The memory card body, in certain embodiments, includes a first surface spaced apart from a second surface and a plurality of side surfaces connecting the first surface to the second surface. The memory card also includes a contact pad disposed on at least one side surface of the plurality of side surfaces. The contact pad includes a first conductive layer, a second conductive layer, and an insulating layer disposed between the first conductive layer and the second conductive layer.

A package structure includes a semiconductor die, an antenna substrate structure, and a redistribution layer. The semiconductor die is laterally wrapped by a first encapsulant. The antenna substrate structure is disposed over the semiconductor die, wherein the antenna substrate structure includes a circuit substrate and at least one antenna element inlaid in the circuit substrate. The redistribution layer is disposed between the semiconductor die and the antenna substrate structure, wherein the at least one antenna element is electrically connected with the semiconductor die through the circuit substrate and the redistribution layer. The at least one antenna element includes patch antennas.

Generally discussed herein are systems, methods, and apparatuses that include conductive pillars that are about co-planar. According to an example, a technique can include growing conductive pillars on respective exposed landing pads of a substrate, situating molding material around and on the grown conductive pillars, removing, simultaneously, a portion of the grown conductive pillars and the molding material to make the grown conductive pillars and the molding material about planar, and electrically coupling a die to the conductive pillars.

Multi-chip systems and structures for modular scaling are described. In some embodiments an interfacing bar is utilized to couple adjacent chips. For example, a communication bar may utilized to coupled logic chips, and memory bar may be utilized to couple multiple memory chips to a logic chip.

RF transistor amplifiers an RF transistor amplifier die having a semiconductor layer structure, an interconnect structure having first and second opposing sides, wherein the first side of the interconnect structure is adjacent a surface of the RF transistor amplifier die such that the interconnect structure and the RF transistor amplifier die are in a stacked arrangement, and one or more circuit elements on the first and/or second side of the interconnect structure.

A semiconductor package includes: a first wiring pattern; a dielectric layer that covers the first wiring pattern; a second wiring pattern on the dielectric layer, wherein the second wiring pattern includes a line part that extends in a first direction and a via part that connects the line part to the first wiring pattern; a pad pattern electrically connected to the second wiring pattern, wherein the pad pattern includes a connection part and an extension part, wherein the connection part covers a first surface of the line part of the second wiring pattern, and the extension part has a top surface at a level lower than a level of the top surface of the line part of the second wiring pattern; and a seed pattern between the extension part and the dielectric layer.