A semiconductor module includes a first power semiconductor device, a conductive wire, and a resin film. The conductive wire is joined to a surface of a first front electrode of the first power semiconductor device. The resin film is formed to be continuous on at least one of an end portion or an end portion of a first joint between the first front electrode and the conductive wire in a longitudinal direction of the conductive wire, a surface of the first front electrode, and a surface of the conductive wire. The resin film has an elastic elongation rate of 4.5% to 10.0%.

A semiconductor device includes: a first electrode terminal; a second electrode terminal; a semiconductor element having an electrode on one surface connected to one surface of the first electrode terminal; a wire that connects an electrode on the other surface of the semiconductor element and the second electrode terminal; and a resin portion formed of an insulator covering the semiconductor element, a part of the second electrode terminal, and the one surface of the first electrode terminal, wherein a chamfered portion is formed on at least one of end portions where the first electrode terminal and the second electrode terminal face each other.

A method of forming a semiconductor device includes providing a substrate that comprises a metal region, forming an encapsulant body of electrically insulating material on an upper surface of the metal region, forming an opening in the encapsulant body, and inserting a press-fit connector into the opening, wherein after inserting the press-fit connector into the opening, the press-fit connector is securely retained to the substrate and an interfacing end of the press-fit connector is electrically accessible.

A semiconductor device and method of manufacturing the same are provided. The semiconductor device includes an interconnect structure on a substrate; a passivation layer disposed on the interconnect structure; a first via, a second via and a third via disposed in the passivation layer and connected to the interconnect structure, each of the first, second and third vias has an elongated shape longitudinally oriented along a first direction; and a first pad longitudinally oriented along the first direction and landing on the first, second and third vias.

In a method of manufacturing a semiconductor device first conductive layers are formed over a substrate. A first photoresist layer is formed over the first conductive layers. The first conductive layers are etched by using the first photoresist layer as an etching mask, to form an island pattern of the first conductive layers separated from a bus bar pattern of the first conductive layers by a ring shape groove. A connection pattern is formed to connect the island pattern and the bus bar pattern. A second photoresist layer is formed over the first conductive layers and the connection pattern. The second photoresist layer includes an opening over the island pattern. Second conductive layers are formed on the island pattern in the opening. The second photoresist layer is removed, and the connection pattern is removed, thereby forming a bump structure.

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.

An inductive structure may be manufactured with in-situ characterization of dimensions by forming a metal line on a top surface of a semiconductor die, forming a passivation dielectric layer over the metal line, measuring a height profile of a top surface of the passivation dielectric layer as a function of a lateral displacement, forming a magnetic material plate over the passivation dielectric layer, measuring a height profile of a top surface of the magnetic material plate as a function of the lateral displacement, and determining a thickness profile of the magnetic material plate by subtracting the height profile of the top surface of the passivation dielectric layer from the height profile of the top surface of the magnetic material plate. An inductive structure including the magnetic material plate and the metal line is formed.

A method for forming a thermal conduction structure includes: a substrate is provided, at least a dielectric layer being formed on the substrate; a Through Silicon Via (TSV) and at least one silicon blind hole are formed, where the at least one silicon blind hole is located on at least one side of the TSV, the TSV penetrates through the substrate and the dielectric layer, and each silicon blind hole does not penetrate through the substrate.

Disclosed is a semiconductor package comprising a first chip stack including on a substrate a plurality of first semiconductor chips in an offset stack structure and stacked to expose a connection region at a top surface of each of the first semiconductor chips, a second semiconductor chip on the substrate and horizontally spaced apart from the first chip stack, a spacer on the second semiconductor chip, and a second chip stack including third semiconductor chips in an offset stack structure on the first chip stack and the spacer. Each of the first semiconductor chips includes a first chip pad on the connection region and a first wire that extends between the first chip pad and the substrate. The first wire of an uppermost one of the first semiconductor chips is horizontally spaced apart from a lowermost one of the third semiconductor chips.

A semiconductor device such as a chip-scale package is provided. Aspects of the present disclosure further relate to a method for manufacturing such a device. According to an aspect of the present disclosure, a semiconductor device is provided that includes a conformal coating arranged on its sidewalls and on the perimeter part of the semiconductor die of the semiconductor device. To prevent the conformal coating from covering unwanted areas, such as electrical terminals, a sacrificial layer is arranged prior to arranging the conformal coating. By removing the sacrificial layer, the conformal coating can be removed locally. The conformal coating covers the perimeter part of the semiconductor die by the semiconductor device, in which part a remainder of a sawing line or dicing street is provided.