Provided is a semiconductor package including an interposer. The semiconductor package includes: a package base substrate; a lower redistribution line structure disposed on the package base substrate and including a plurality of lower redistribution line patterns; at least one interposer including a plurality of first connection pillars spaced apart from each other on the lower redistribution line structure and connected respectively to portions of the plurality of lower redistribution line patterns, and a plurality of connection wiring patterns; an upper redistribution line structure including a plurality of upper redistribution line patterns connected respectively to the plurality of first connection pillars and the plurality of connection wiring patterns, on the plurality of first connection pillars and the at least one interposer; and at least two semiconductor chips adhered on the upper redistribution line structure while being spaced apart from each other.

A semiconductor module includes: a switching device including a gate pad; an output unit including an output pad connected with the gate pad of the switching device through a wire and outputting a drive signal from the output pad to the switching device; a temperature protection circuit detecting temperature and performing protection operation; and a heat conduction pattern connected with the output pad, extending from the output pad toward the temperature protection circuit, and conducting heat generated at the switching device to the temperature protection circuit.

A semiconductor device has a substrate, a first circuit, a first inductor, a second circuit and a second inductor IND2. The substrate includes a first region and a second region, which are regions different from each other. The first circuit is formed on the first region. The first inductor is electrically connected with the first circuit. The second circuit is formed on the second regions. The second inductor is electrically connected with the second circuit and formed to face the first inductor. A penetrating portion is formed in the substrate. The penetrating portion is formed such that the penetrating portion surrounds one or both of the first circuit and the second circuit in plan view.

Implementations of semiconductor packages may include a die having a first side and a second side opposite the first side, a first metal layer coupled to the first side of the die, a tin layer coupled to the first metal layer, the first metal layer between the die and the tin layer, a backside metal layer coupled to the second side of the die, and a mold compound coupled to the die. The mold compound may cover a plurality of sidewalls of the first metal layer and a plurality of sidewalls of the tin layer and a surface of the mold compound is coplanar with a surface of the tin layer.

A semiconductor device includes a substrate, conductive features on the substrate, and a passivation layer over the conductive features to define conductive pads in the respective conductive features through exposed portions of each of the conductive features. Each corner of the conductive pads is free of right angle, the substrate has a pair of long sides from a top view perspective, the shape of each of the conductive pads is a parallelogram. Each of the conductive pads has a pair of long sides and a pair of short sides from a top view perspective, a portion of the conductive pads have the long sides sloped away from a first pad density area of the substrate and toward one long side of the substrate, and the rest of the conductive pads have the long sides sloped toward the first pad density area and toward the other long side of the substrate.

A power module includes at least two power units. Each power unit includes at least one power semiconductor and a substrate. In order to reduce the installation space required for the power module and to improve cooling, the at least one power semiconductor is connected, in particular in a materially bonded manner, to the substrate. The substrates of the at least two power units are each directly connected in a materially bonded manner to a surface of a common heat sink. A power converter having at least one power module is also disclosed.

The semiconductor device includes a semiconductor element, a first lead, and a second lead. The semiconductor element has an element obverse surface and an element reverse surface spaced apart from each other in a thickness direction. The semiconductor element includes an electron transit layer disposed between the element obverse surface and the element reverse surface and formed of a nitride semiconductor, a first electrode disposed on the element obverse surface, and a second electrode disposed on the element reverse surface and electrically connected to the first electrode. The semiconductor element is mounted on the first lead, and the second electrode is joined to the first lead. The second lead is electrically connected to the first electrode. The semiconductor element is a transistor. The second lead is spaced apart from the first lead and is configured such that a main current to be subjected to switching flows therethrough.

There is provided semiconductor devices and methods of forming the same, the semiconductor devices including: a first semiconductor element having a first electrode; a second semiconductor element having a second electrode; a Sn-based micro-solder bump formed on the second electrode; and a concave bump pad including the first electrode opposite to the micro-solder bump, where the first electrode is connected to the second electrode via the micro-solder bump and the concave bump pad.

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.

Memory devices are disclosed. A memory device may include a command and address (CA) interface region including a first CA input circuit configured to generate a first CA output AND a second CA input circuit configured to generate a second CA output. The first CA input circuit and the second CA input circuit are arranged in a mirror relationship. The CA interface region further includes a swap circuit configured to select one of the first CA output and the second CA output for a first internal CA signal and select the other of the first CA output and the second CA output for a second internal CA signal. Memory systems and systems are also disclosed.