A device is disclosed which includes at least one integrated circuit die, at least a portion of which is positioned in a body of encapsulant material, and at least one conductive via extending through the body of encapsulant material.

A semiconductor device includes an interposer disposed on a substrate. A first major surface of the interposer faces the substrate. A system on a chip is disposed on a second major surface of the interposer. The second major surface of the interposer opposes the first major surface of the interposer. A plurality of first passive devices is disposed in the first major surface of the interposer. A plurality of second passive devices is disposed on the second major surface of the interposer. The second passive devices are different devices than the first passive devices.

Aspects of the disclosure provide a semiconductor apparatus including a plurality of structures. A first one of the structures comprises a first stack of transistors that includes a first transistor formed on a substrate and a second transistor stacked on the first transistor along a Z direction substantially perpendicular to a substrate plane of the semiconductor apparatus. The first one of the structures further includes local interconnect structures. The first transistor is sandwiched between two of the local interconnect structures. The first one of the structures further includes vertical conductive structures substantially parallel to the Z direction. The vertical conductive structures are configured to provide at least power supplies for the first one of the structures by electrically coupling with the local interconnect structures. A height of one of the vertical conductive structures along the Z direction is at least a height of the first one of the structures.

A semiconductor package includes a silicon substrate including a cavity and a plurality of through holes spaced apart from the cavity, a first semiconductor chip in the cavity, a plurality of conductive vias in the plurality of through holes, a first redistribution layer on the silicon substrate and connected to the first semiconductor chip and the conductive vias, and a second redistribution layer below the silicon substrate and connected to the first semiconductor chip and the plurality of conductive vias.

We herein describe a semiconductor device sub-assembly comprising at least two power semiconductor devices and a contact of a first type. A first power semiconductor device is located on a first side of the contact of a first type, and a second power semiconductor device is located on a second side of the contact of a first type, where the second side is opposite to the first side.

Embodiments of the invention include molded modules and methods for forming molded modules. According to an embodiment the molded modules may be integrated into an electrical package. Electrical packages according to embodiments of the invention may include a die with a redistribution layer formed on at least one surface. The molded module may be mounted to the die. According to an embodiment, the molded module may include a mold layer and a plurality of components encapsulated within the mold layer. Terminals from each of the components may be substantially coplanar with a surface of the mold layer in order to allow the terminals to be electrically coupled to the redistribution layer on the die. Additional embodiments of the invention may include one or more through mold vias formed in the mold layer to provide power delivery and/or one or more faraday cages around components.

Provided is a semiconductor package modularized and manufactured by preparing a main block for putting on a semiconductor chip, an insulator, and one or more sub block, preparing the semiconductor chip, preparing an adhesive used in attaching the semiconductor chip, attaching the semiconductor chip to an upper surface or upper and lower surfaces of the main block, performing an electrical connection of the semiconductor chip, preparing a substrate comprising a pattern enabling an electrical connection and vertically attaching one side of the main block to the pattern of the substrate to enable an electrical connection. In the semiconductor package above, an accumulation rate increases on the substrate due to a vertically arranged structure of the semiconductor chips and a heat emission area is enlarged to improve a heat emission effect.

A package includes a corner, a device die, a molding material molding the device die therein, and a plurality of bonding features. The plurality of bonding features includes a corner bonding feature at the corner, wherein the corner bonding feature is elongated. The plurality of bonding features further includes an additional bonding feature, which is non-elongated.

A semiconductor chip stack module that includes a substrate, two first semiconductor chips supported by the substrate, and a second semiconductor chip stacked on both of the two first semiconductor chips. The second semiconductor chip is electrically connected to both of the two first semiconductor chips by a conductive paste configured between the second semiconductor chip and both of the two first semiconductor chips. As multiple standard chips are stacked in the power module, and their number as well as the connection methods (e.g. series or parallel) are flexible so that the user can choose which electric characteristic(s) to be increased in the power module with the stacked chips.

Disclosed is a semiconductor package comprising a package substrate, a first semiconductor chip on the package substrate and including a first region and a second region, a second semiconductor chip on the first region, a heat radiation spacer on the second region, a third semiconductor chip supported by the second semiconductor chip and the heat radiation spacer, and a molding layer covering the first to third semiconductor chips and the heat radiation spacer.