A camera assembly includes a photosensitive unit, including a photosensitive chip and an optical filter mounted on the photosensitive chip; functional components; and an encapsulation layer, embedded with the photosensitive unit and the functional components. The photosensitive chip and the functional components are exposed from a bottom surface of the encapsulation layer. A top surface of the encapsulation layer is higher than the photosensitive chip and functional components and exposes the optical filter. The photosensitive chip has soldering pads facing away from the bottom surface of the encapsulation layer. The functional components have soldering pads exposed from the bottom surface of the encapsulation layer. The camera assembly further includes a redistribution layer structure, disposed on the bottom surface of the encapsulation layer and electrically connecting to the soldering pads.

A semiconductor package includes a first chip, a first chip and a molding compound. The first chip has a first via protruding from the first chip. The second chip has a second via protruding from the second chip, wherein a thickness of the first chip is different from a thickness of the second chip. The molding compound encapsulates the first chip, the second chip, the first via and the second via, wherein surfaces of the first via, the second via and the molding compound are substantially coplanar.

The present disclosure provides a method for packaging a camera assembly. The method includes: providing a photosensitive chip; mounting an optical filter on the photosensitive chip; temporarily bonding the photosensitive chip and functional components on a carrier substrate, where the photosensitive chip has soldering pads facing away from the carrier substrate and the functional components have soldering pads facing toward the carrier substrate; forming an encapsulation layer covering the carrier substrate, the photosensitive chip, and the functional components, and exposing the optical filter; after the encapsulation layer is formed, removing the carrier substrate; and after the carrier substrate is removed, forming a redistribution layer structure on a side of the encapsulation layer facing away from the optical filter to electrically connect the soldering pads of the photosensitive chip with the soldering pads of the functional components.

A semiconductor package having an aperture in a die pad and solder in the aperture coplanar with a surface of the package is disclosed. The package includes a die pad, a plurality of leads, and a semiconductor die coupled to the die pad with a die attach material. A cavity or aperture is formed through the die pad to expose a portion of the die attach material. Multiple solder reflows are performed to reduce the presence of voids in the die attach material. In a first solder reflow, the voids of trapped gas that form when attaching the die to the die pad are released. Then, in a second solder reflow, solder is added to the aperture coplanar with a surface of the die pad. The additional solder can be the same material as the die attach material or a different material.

A semiconductor device includes a support, a semiconductor chip, a first insulating film, and a wiring layer. The support comprises a first electrode. The semiconductor chip has a first surface facing the support and a second surface facing away from the support with a second electrode thereon. The first insulating film has a first portion in contact with the first surface and a second portion in contact with at least one side surface of the semiconductor chip. The wiring layer connects the first electrode to the second electrode. The wiring layer is on the support, the second surface of the semiconductor chip, a side surface of the second portion of the first insulating film.

An integrated circuit package can contain a semiconductor die and provide electrical connections between the semiconductor die and additional electronic components. The integrated circuit package can reduce stress placed on the semiconductor die due to movement of the integrated circuit package due to, for example, temperature changes and/or moisture levels. The integrated circuit package can at least partially mechanically isolate the semiconductor die from the integrated circuit package.

A leadless packaged semiconductor device includes a metal substrate having at least a first through-hole aperture having a first outer ring and a plurality of cuts through the metal substrate to define spaced apart metal pads on at least two sides of the first through-hole aperture. A semiconductor die that has a back side metal (BSM) layer on its bottom side and a top side with circuitry coupled to bond pads is mounted top side up on the first outer ring. A metal die attach layer is directly between the BSM layer and walls of the metal substrate bounding the first through-hole aperture that provides a die attachment that fills a bottom portion of the first through-hole aperture. Bond wires are between metal pads and the bond pads. A mold compound is also provided including between adjacent ones of the metal pads.

A semiconductor package having an aperture in a die pad and solder in the aperture coplanar with a surface of the package is disclosed. The package includes a die pad, a plurality of leads, and a semiconductor die coupled to the die pad with a die attach material. A cavity or aperture is formed through the die pad to expose a portion of the die attach material. Multiple solder reflows are performed to reduce the presence of voids in the die attach material. In a first solder reflow, the voids of trapped gas that form when attaching the die to the die pad are released. Then, in a second solder reflow, solder is added to the aperture coplanar with a surface of the die pad. The additional solder can be the same material as the die attach material or a different material.

A leadless packaged semiconductor device includes a metal substrate having at least a first through-hole aperture having a first outer ring and a plurality of cuts through the metal substrate to define spaced apart metal pads on at least two sides of the first through-hole aperture. A semiconductor die that has a back side metal (BSM) layer on its bottom side and a top side with circuitry coupled to bond pads is mounted top side up on the first outer ring. A metal die attach layer is directly between the BSM layer and walls of the metal substrate bounding the first through-hole aperture that provides a die attachment that fills a bottom portion of the first through-hole aperture. Bond wires are between metal pads and the bond pads. A mold compound is also provided including between adjacent ones of the metal pads.

A leadless packaged semiconductor device includes a metal substrate having at least a first through-hole aperture having a first outer ring and a plurality of cuts through the metal substrate to define spaced apart metal pads on at least two sides of the first through-hole aperture. A semiconductor die that has a back side metal (BSM) layer on its bottom side and a top side with circuitry coupled to bond pads is mounted top side up on the first outer ring. A metal die attach layer is directly between the BSM layer and walls of the metal substrate bounding the first through-hole aperture that provides a die attachment that fills a bottom portion of the first through-hole aperture. Bond wires are between metal pads and the bond pads. A mold compound is also provided including between adjacent ones of the metal pads.