A method of forming a semiconductor device includes attaching a first semiconductor device to a first surface of a substrate; forming a sacrificial structure on the first surface of the substrate around the first semiconductor device, the sacrificial structure encircling a first region of the first surface of the substrate; and forming an underfill material in the first region.

A packaging substrate includes a core layer including a glass substrate with a first surface and a second surface facing each other, and a plurality of core vias. The plurality of core vias penetrating through the glass substrate in a thickness direction, each comprising a circular core via having a circular opening part and a non-circular core via having an aspect ratio of 2 to 25 in the x-y direction of an opening part. One or more electric power transmitting elements are disposed on the non-circular core via.

A chip package structure is provided. The chip package structure includes a substrate. The chip package structure includes a chip package stacked over the substrate. The chip package structure includes first conductive bumps arranged between and in direct contact with the chip package and the substrate providing a clearance. The chip package structure includes a chip structure having a first face and an opposing second face arranged in the clearance between the chip package and the substrate and adjacent to the first conductive bumps. The chip structure contains at least one chip. The chip package structure includes a solder cap connecting the first face of the chip structure and the chip package. The chip package structure includes a second conductive bump connecting the second face of the chip structure and the substrate.

A semiconductor package includes first bump pads on a first surface of an interconnection structure layer, elevated pads thicker than the first bump pads on the first surface of the interconnection structure layer, a first semiconductor device connected on the first bump pads, through mold ball connectors connected on the elevated pads, respectively, a molding layer disposed covering the first surface of the interconnection structure layer to expose a portion of each of the through mold ball connectors, outer connectors respectively attached to the through mold ball connectors, and a second semiconductor device on a second surface of the interconnection structure layer opposite to the molding layer.

A semiconductor package includes first bump pads on a first surface of an interconnection structure layer, elevated pads thicker than the first bump pads on the first surface of the interconnection structure layer, a first semiconductor device connected on the first bump pads, through mold ball connectors connected on the elevated pads, respectively, a molding layer disposed covering the first surface of the interconnection structure layer to expose a portion of each of the through mold ball connectors, outer connectors respectively attached to the through mold ball connectors, and a second semiconductor device on a second surface of the interconnection structure layer opposite to the molding layer.

According to one embodiment, M (M represents an integer of 2 or larger) semiconductor chips and through electrodes for N (N represents an integer of 2 or larger) channels are provided. The M semiconductor chips are stacked in sequence. The through electrodes are embedded in the semiconductor chips to connect electrically the semiconductor chips in the direction of stacking. The connection destination of the through electrodes are exchanged between one or more upper and lower layers of the semiconductor chips.

Disclosed herein is an apparatus that includes a first semiconductor chip, and a first TSV penetrating the first semiconductor chip. The first semiconductor chip includes a first resistor coupled between a first power supply and a first node, a switch circuit coupled between the first node and the first TSV, a pad electrode operatively coupled to the first node, and a constant current source operatively coupled to either one of the first node and the pad electrode.

Apparatuses and methods using a silicon on insulator (SOI) substrate are described. An example apparatus includes: a substrate including a first surface and a second surface opposite to the first surface; a circuit formed in the first surface; a first electrode through the substrate from the first surface to the second surface; and a first insulative film around the first electrode. The first electrode includes: a first portion formed in the substrate; and a second portion continuous to the first portion and protruding from the second surface. The first insulative film is formed between the first portion of the first electrode in the substrate and extending to a side surface of the second portion of the first electrode.

A stacked semiconductor package includes a first semiconductor chip having a first active surface over which first bonding pads including peripheral bonding pads and central bonding pads are arranged, a first encapsulation member, two second semiconductor chips having second active surfaces over which second bonding pads are arranged at one side peripheries and disposed to be separated from each other such that the second active surfaces face the first active surface and the second bonding pads overlap with the peripheral bonding pads, first coupling members interposed between the peripheral bonding pads and the second bonding pads, a second encapsulation member formed over second side surfaces of the second semiconductor chips including a region between the second semiconductor chips, and a mold via formed through a portion of the second encapsulation member in the region between the second semiconductor chips and coupled with the central bonding pads.

A micro-component comprises a component substrate having a first side and an opposing second side. Fenders project from the first and second sides of the component substrate and include first-side fenders extending from the first side and a second-side fender extending from the second side of the component substrate. At least two of the first-side fenders have a non-conductive surface and are disposed closer to a corner of the component substrate than to a center of the component substrate.