A package structure, a packaging method and a semiconductor device are provided. The method includes: providing a semiconductor functional structure, an interconnecting layer disposed on a surface of the semiconductor functional structure; forming an isolation layer exposing part of the interconnecting layer, the exposed part of the interconnecting layer acting as a first pad, and the first pad used for performing a first type test; after completing the first type test, forming a redistribution layer on the first pad and the isolation layer, the redistribution layer and the interconnecting layer electrically connected; and forming a first insulating layer exposing parts of the redistribution layer, the exposed parts of the redistribution layer acting as a second pad and a third pad, the second pad used for performing a second type test, and the third pad used for executing a functional interaction corresponding to contents of the second type test.

A semiconductor device includes a pad formed on a surface of a substrate, a bonding wire for connecting the pad to an external circuit, and a resin layer covering at least a connection portion between the pad and the bonding wire and exposing at least a part of the substrate outside the pad.

A lead frame includes a support portion that has one end on which a first part and a second part that has a smaller thickness than the first part are arranged, a lead, and a heat sink that is welded to the support portion in the second part. A method of manufacturing the lead frame includes forming, from a metal plate, a frame member that includes a support portion and a lead, where the support portion has one end on which a first part and a second part that has a smaller thickness than the first part are arranged, and welding a heat sink to the support portion in the second part.

A semiconductor package structure includes a carrier, an electronic device, a spacer, a transparent panel, and a conductive wire. The electronic device has a first surface and an optical structure on the first surface. The spacer is disposed on the first surface to enclose the optical structure of the electronic device. The transparent panel is disposed on the spacer. The conductive wire electrically connects the electronic device to the carrier and is exposed to air.

A semiconductor device is provided, which is configured to improve the adhesion between the resin part and the leads without interfering with proper operation of the semiconductor device. The semiconductor device includes a semiconductor element 1, a first lead 2 including a first pad portion 21, a second lead 3 including a second pad portion 31, a conductor member 61, and a resin part 8. The first pad portion 21 has a first-pad obverse surface 21a including a first smooth region 211 to which an element reverse surface 1b is bonded, and a first rough region 212 spaced apart from the semiconductor element 1 as viewed in z direction and has a higher roughness than the first smooth region 211. The second pad portion 31 has a second-pad obverse surface 31a including a second smooth region 311 to which a second bonding portion 612 is bonded, and a second rough region 312 spaced apart from the second bonding portion 612 as viewed in z direction and has a higher roughness than the second smooth region 311.

A semiconductor device includes a semiconductor element, a sealing material, and an extension wire. The semiconductor element has, on a front surface, a first electrode pad and at least one second electrode pad, and generates a current in a direction connecting the front surface and a back surface. The sealing material is made of an insulating resin material and covers a part of the front surface and a side surface of the semiconductor element. The extension wire is disposed above the semiconductor element and inside the sealing material or on the sealing material. The extension wire is electrically connected to the second electrode pad, and extends from a position inside of a contour of the semiconductor element to a position outside of the contour of the semiconductor element.

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.

A method for manufacturing a semiconductor device includes a step of preparing a semiconductor substrate that has a first main surface on one side and a second main surface on the other side, the semiconductor substrate on which a plurality of device forming regions and an intended cutting line that demarcates the plurality of device forming regions are set, a step of forming a first electrode that covers the first main surface in each of the device forming regions, a step of forming a second electrode that covers the second main surface, a step of partially removing the second electrode along the intended cutting line such that the semiconductor substrate is exposed, and forming a removed portion that extends along the intended cutting line, and a step of cutting the semiconductor substrate along the removed portion.

A semiconductor module includes an insulating plate, a graphite plate and a semiconductor element. The graphite plate is provided by a stack of graphene layers. The graphite plate has a first surface joined to the insulating plate, and a second surface opposite to the first surface. The semiconductor element is disposed adjacent to the second surface of the graphite plate. The insulating plate extends from the graphite plate in a plan view in a direction normal to the graphite plate.

A semiconductor device includes an insulating layer, a semiconductor element, a wiring layer and a sealing resin. The insulating layer includes obverse and reverse surfaces spaced apart in a thickness direction, and a penetrated part extending in the thickness direction. The semiconductor element, in contact with the obverse surface, includes an electrode corresponding to the penetrated part. The wiring layer includes connecting and main parts, where the connecting part is in the penetrated part and contacts the electrode, and the main part is connected to the connecting part on the reverse surface. The sealing resin, contacting the obverse surface, covers the semiconductor element. The electrode has a connecting surface facing the connecting part and including a first region exposed from the insulating layer through the penetrated part and a second region contacting the insulating layer. The first region has a greater surface roughness than the second region.