A fan-out semiconductor package includes a first connection structure having first and second surfaces, a first semiconductor chip disposed on the first surface, a first encapsulant disposed on the first surface and covering at least a portion of the first semiconductor chip, a second semiconductor chip disposed on the second surface, one or more first metal members disposed on the second surface, one or more second metal members disposed on the second surface, a second encapsulant disposed on the second surface and respectively covering at least portions of the second semiconductor chip and the first and second metal members, and a second connection structure disposed on an opposite side of a side of the second encapsulant, on which the first connection structure is disposed.

Stacked microfeature devices and associated methods of manufacture are disclosed. A package in accordance with one embodiment includes first and second microfeature devices having corresponding first and second bond pad surfaces that face toward each other. First bond pads can be positioned at least proximate to the first bond pad surface and second bond pads can be positioned at least proximate to the second bond pad surface. A package connection site can provide electrical communication between the first microfeature device and components external to the package. A wirebond can be coupled between at least one of the first bond pads and the package connection site, and an electrically conductive link can be coupled between the first microfeature device and at least one of the second bond pads of the second microfeature device. Accordingly, the first microfeature device can form a portion of an electrical link to the second microfeature device.

A semiconductor package includes a semiconductor chip having chip pads on a first surface and having first and second side surfaces opposite to each other and third and fourth side surfaces opposite to each other, a molding member covering the third and fourth side surfaces and exposing the first and second side surfaces of the semiconductor chip, a redistribution wiring layer on a lower surface of the molding member to cover the first surface of the semiconductor chip and including a plurality of redistribution wirings electrically connected to the chip pads, and outer connection members arranged in a connection region defined on an outer surface of the redistribution wiring layer and electrically connected to the redistribution wirings.

The present application discloses a semiconductor device and a method for fabricating the semiconductor device. The semiconductor device includes a substrate, a first pad positioned above the substrate, and a first redistribution structure including a first redistribution conductive layer positioned on the first pad and a first redistribution thermal release layer positioned on the first redistribution conductive layer. The first redistribution thermal release layer is configured to sustain a thermal resistance between about 0.04° C. cm.sup.2/Watt and about 0.25° C. cm.sup.2/Watt.

Implementations of image sensor packages may include an image sensor chip, a first layer including an opening therethrough coupled to a first side of the image sensor chip, and a optically transmissive cover coupled to the first layer. The optically transmissive cover, the first layer, and the image sensor chip may form a cavity within the image sensor. The image sensor package may also include at least one electrical contact coupled to a second side of the image sensor chip opposing the first side and an encapsulant coating an entirety of the sidewalls of the image sensor package.

A stack package includes a first sub-package and a second sub-package stacked on the first sub-package. The first sub-package includes a first through mold via (TMV) for connection spaced apart from a first semiconductor chip in an X-axis direction, a first TMV for bypass spaced apart from the first semiconductor chip in a Y-axis direction, and a first redistribution line (RDL) pattern connecting the first semiconductor chip to the first TMV for connection. The second sub-package includes a second TMV for connection spaced apart from a second semiconductor chip in the Y-axis direction and another RDL pattern connecting the second semiconductor chip to the second TMV for connection. the second sub-package is stacked on the first sub-package such that the second TMV for connection is connected to the first TMV for bypass.

A semiconductor package includes a connection structure having including a plurality of insulating layers and redistribution layers on the plurality of insulating layers. A semiconductor chip has connection pads connected to the redistribution layers, and an encapsulant encapsulates the semiconductor chip. A passive component is embedded in the connection structure and has connection terminals connected to the redistribution layer. The redistribution layers include a plurality of redistribution patterns, each disposed on the plurality of insulating layers and a plurality of redistribution vias each penetrating through the plurality of insulating layers and connected to the plurality of redistribution patterns. The plurality of redistribution vias include a plurality of blocking vias arranged to surround the passive component, and the plurality of redistribution patterns include a blocking pattern connected to adjacent blocking vias.

The present technology relates to an imaging device, an electronic apparatus, and a method of manufacturing an imaging device capable of thinning a semiconductor on a terminal extraction surface while maintaining a strength of a semiconductor chip. There is provided an imaging device including: a first substrate having a pixel region in which pixels are two-dimensionally arranged, the pixels performing photoelectric conversion of light; and a second substrate in which a through silicon via is formed, in which a dug portion is formed in a back surface of the second substrate opposite to an incident side of light of the second substrate, and a redistribution layer (RDL) connected to a back surface of the first substrate is formed in the dug portion. The present technology can be applied to, for example, a semiconductor package including a semiconductor chip.

In one example, a semiconductor device can comprise (a) an electronic device comprising a device top side, a device bottom side opposite the device top side, and a device sidewall between the device top side and the device bottom side, (b) a first conductor comprising, a first conductor side section on the device sidewall, a first conductor top section on the device top side and coupled to the first conductor side section, and a first conductor bottom section coupled to the first conductor side section, and (c) a protective material covering the first conductor and the electronic device. A lower surface of the first conductor top section can be higher than the device top side, and an upper surface of the first conductor bottom section can be lower than the device top side. Other examples and related methods are also disclosed herein.

Provided is a semiconductor package including a semiconductor stack including a first lower chip, a second lower chip, a gap filler disposed between the first lower chip and the second lower chip, and a first upper chip disposed on an upper surface of the first lower chip, an upper surface of the second lower chip, and an upper surface of the gap filler, the first lower chip includes first upper surface pads and a first upper surface dielectric layer, the second lower chip includes second upper surface pads and a second upper surface dielectric layer, the first upper chip includes lower surface pads and a lower surface dielectric layer, and an area of an upper surface of each of the second upper surface pads is greater than an area of a lower surface of each of the lower surface pads.