A power electronic assembly includes a board having metal layers laminated onto or between electrically insulating layers, and a laminate inlay embedded in the board. A first metal layer provides electrical contacts at a first side of the board. A second metal layer provides a thermal contact at a second side of the board. A third metal layer is positioned between the first metal layer and the laminate inlay and configured to distribute a load current switched by the laminate inlay. A fourth metal layer is positioned between the second metal layer and the laminate inlay and configured as a primary thermal conduction path for heat generated by the laminate inlay during switching of the load current. A first electrically insulating layer separates the fourth metal layer from the second metal layer so that the fourth metal layer is electrically isolated from but thermally connected to the second metal layer.

An electronic device and a method of manufacturing an electronic device. As non-limiting examples, various aspects of this disclosure provide various methods of manufacturing electronic devices, and electronic devices manufactured thereby, that comprise utilizing metal studs to further set a semiconductor die into the encapsulant.

A method for manufacturing a semiconductor package may include: forming a photoimageable dielectric layer on a substrate including a pad; forming a preliminary via hole in the photoimageable dielectric layer to expose the pad; forming a hard mask layer on the photoimageable dielectric layer and the pad; etching the photoimageable dielectric layer and the hard mask layer to form a via hole, a first hole, and a trench; forming a metal layer on the photoimageable dielectric layer connected to the pad; planarizing the metal layer to form a wiring pattern; and placing a semiconductor chip electrically connected to the wiring pattern. The first hole may be disposed on the via hole and connected thereto, and a diameter of the first hole may be larger than a diameter of the via hole.

A high voltage semiconductor package includes a semiconductor device. The semiconductor device includes a high voltage semiconductor transistor chip having a front side and a backside. A low voltage load electrode and a control electrode are disposed on the front side of the semiconductor transistor chip. A high voltage load electrode is disposed on the backside of the semiconductor transistor chip. The semiconductor package further includes a dielectric inorganic substrate. The dielectric inorganic substrate includes a pattern of first metal structures running through the dielectric inorganic substrate and connected to the low voltage load electrode, and at least one second metal structure running through the dielectric inorganic substrate and connected to the control electrode. The front side of the semiconductor transistor chip is attached to the dielectric inorganic substrate by a wafer bond connection, and the dielectric inorganic substrate has a thickness of at least 50 μm.

A semiconductor chip package includes a substrate having a top surface and a bottom surface, and a semiconductor device mounted on the top surface of the substrate. A gap is provided between the semiconductor device and the top surface of the substrate. A multi-layer laminate epoxy sheet is disposed on the top surface of the substrate and around a perimeter of the semiconductor device.

A circuit structure is provided. The circuit structure may include a first die area including an output gate, a second die area including a circuit and an input gate and a die-to-die interconnect. The input gate may include a transistor. The circuit may be connected between the die-to-die interconnect and a gate region of the transistor. The circuit may include a MOS transistor. A first source/drain region of the MOS transistor may be connected to the die-to-die interconnect.

A method for contacting and rewiring an electronic component embedded in a PCB in the following manner is disclosed. A first permanent resist layer is applied to one contact side of the PCB. The first permanent resist layer is structured to produce exposures in the area of contacts of the electronic component. A second permanent resist layer is applied onto the structured first permanent resist layer. The second permanent resist layer is structured to expose the exposures in the area of the contacts and to produce exposures in line with the desired conductor tracks. The exposures are chemically coated with copper the copper is electric-plated to the exposures. Excess copper in the areas between the exposures is removed.

A device includes a first semiconductor chip including a first face, wherein a first contact pad is arranged over the first face. The device further includes a second semiconductor chip including a first face, wherein a first contact pad is arranged over the first face, wherein the first semiconductor chip and the second semiconductor chip are arranged such that the first face of the first semiconductor chip faces in a first direction and the first face of the second semiconductor chip faces in a second direction opposite to the first direction. The first semiconductor chip is located laterally outside of an outline of the second semiconductor chip.

Various embodiments may provide a semiconductor package. The semiconductor package may include a semiconductor chip, a first mold compound layer at least partially covering the semiconductor chip, and a redistribution layer over the first mold compound layer, the redistribution layer including one or more electrically conductive lines in electrical connection with the semiconductor chip. The semiconductor package may additionally include a second mold compound layer over the redistribution layer, and an antenna array over the second mold compound layer, the antenna array configured to be coupled to the one or more electrically conductive lines.

A semiconductor device and a method of manufacturing a semiconductor device. As a non-limiting example, various aspects of this disclosure provide a semiconductor device comprising multiple encapsulating layers and multiple signal distribution structures, and a method of manufacturing thereof.