The present disclosure relates to a power module comprising a substrate, first and second pluralities of vertical power devices, and first and second terminal assemblies. The substrate has a top surface with a first trace and a second trace. The first plurality of vertical power devices and a second plurality of vertical power devices are electrically coupled to form part of a power circuit. The first plurality of vertical power devices are electrically and mechanically directly coupled between the first trace and a bottom of a first elongated bar of the first terminal assembly. The second plurality of vertical power devices are electrically and mechanically directly coupled between the second trace and a bottom of a second elongated bar of the second terminal assembly.

A semiconductor package includes: a package substrate including a plurality of insulating layers and a plurality of metal pattern layers respectively disposed on the plurality of insulating layers, wherein each of the plurality of metal pattern layers has an interconnection layer; at least one semiconductor chip disposed on an upper surface of the package substrate, and connected to the interconnection layer; contact pads disposed on a lower surface of the package substrate, and connected to the interconnection layer; and non-contact pads disposed on the lower surface of the package substrate, and insulated from the interconnection layer, wherein a lowermost metal pattern layer among the plurality of metal pattern layers has a first open region at least partially overlapping at least one non-contact pad among the non-contact pads, in a direction perpendicular to the upper surface of the package substrate.

A non-volatile storage system includes a memory controller connected to an integrated memory assembly. The integrated memory assembly includes a memory die comprising non-volatile memory cells and a control die bonded to the memory die. The memory controller provides data to the control die for storage on the memory die. Data is initially stored on the memory die as single bit per memory cell data to increase the performance of the programming process. Subsequently, the control die performs an adaptive folding process which comprises reading the single bit per memory cell data from the memory die, adaptively performing one of multiple decoding options, and programming the data back to the memory die as multiple bit per memory cell data.

An apparatus including a circuit structure including a device stratum; one or more electrically conductive interconnect levels on a first side of the device stratum and coupled to ones of the transistor devices; and a substrate including an electrically conductive through silicon via coupled to the one or more electrically conductive interconnect levels so that the one or more interconnect levels are between the through silicon via and the device stratum. A method including forming a plurality of transistor devices on a substrate, the plurality of transistor devices defining a device stratum; forming one or more interconnect levels on a first side of the device stratum; removing a portion of the substrate; and coupling a through silicon via to the one or more interconnect levels such that the one or more interconnect levels is disposed between the device stratum and the through silicon via.

Provided are an integrated voltage regulator (IVR) package with a minimized size including one or more inductors and one or more capacitors together with an IVR chip and improving characteristics of a voltage regulator (VR), and an IVR system package including the IVR package. The IVR package includes a package substrate, a stacked structure mounted on the package substrate and having a stack structure in which a passive device chip including one or more capacitors and an IVR chip including a voltage regulator are stacked, and an intermediate substrate disposed on the package substrate in a structure surrounding the stacked structure, the intermediate substrate including vias therein. The one or more inductors are included in the stacked structure or the intermediate substrate.

A package structure includes a first chip, a first redistribution layer, a second chip, a second redistribution layer, a third redistribution layer, a carrier, and a first molding compound layer. The first redistribution layer is arranged on a surface of the first chip. The second redistribution layer is arranged on a surface of the second chip. The third redistribution layer interconnects the first redistribution layer and the second redistribution layer. The carrier is arranged on a side of the third redistribution layer away from the first redistribution layer and the second redistribution layer. The first molding compound layer covers the first chip, the first redistribution layer, the second chip, and the second redistribution layer. A manufacturing method is also disclosed.

A semiconductor device of an embodiment includes: a first semiconductor element; a first insulating resin that seals the first semiconductor element; a wiring substrate having a pad; a first wiring that extends from the first semiconductor element toward the wiring substrate, and has a first head portion and a first column portion, the first column portion connected to the first semiconductor element and the first head portion exposed on a surface of the first insulating resin; and a first conductive bonding agent that electrically connects the first head portion of the first wiring and the pad. When a surface of the first head portion facing a side of the first insulating resin is defined as a first surface. A surface of the first insulating resin on a side of the wiring substrate is defined as a second surface. A distance from a surface of the wiring substrate on a side of the first insulating resin to the first surface is defined as a first distance, and a distance from a surface of the wiring substrate on the side of the first insulating resin to the second surface is defined as a second distance. The first distance is shorter than the second distance.

Embodiments of the present disclosure are directed to a leadframe package with recesses formed in outer surface of the leads. The recesses are filled with a filler material, such as solder. The filler material in the recesses provides a wetable surface for filler material, such as solder, to adhere to during mounting of the package to another device, such as a printed circuit board (PCB). This enables strong solder joints between the leads of the package and the PCB. It also enables improved visual inspection of the solder joints after the package has been mounted.

Embodiments of the present disclosure are directed to a leadframe package with recesses formed in outer surface of the leads. The recesses are filled with a filler material, such as solder. The filler material in the recesses provides a wetable surface for filler material, such as solder, to adhere to during mounting of the package to another device, such as a printed circuit board (PCB). This enables strong solder joints between the leads of the package and the PCB. It also enables improved visual inspection of the solder joints after the package has been mounted.

An apparatus includes an integrated circuit and a substrate coupled to the integrated circuit. The substrate includes a primary layer having a first surface that is a first external surface of the substrate. The primary layer includes an open area that extends through the primary layer to an inner layer of the substrate. The substrate includes a secondary layer. The inner layer is located between the primary layer and the secondary layer. The inner layer includes a third surface that is orientated approximately parallel to the first surface of the primary layer. A portion of the third surface of the inner layer is exposed via the open area of the primary layer. A first plurality of wire bond pads are disposed on the portion of the third surface of the inner layer that is exposed via the open area of primary layer.