A semiconductor device includes a first chip, a dielectric layer over the first chip, and a second chip over the dielectric layer. A conductive layer is embedded in the dielectric layer and is electrically coupled to the first chip and the second chip. The second chip includes an optical component. The first chip and the second chip are arranged on opposite sides of the dielectric layer in a thickness direction of the dielectric layer.

Embodiments of the present invention are directed to a method of manufacturing a semiconductor package with an internal routing circuit. The internal routing circuit is formed from multiple molding routing layers in a plated and etched copper terminal semiconductor package by using an inkjet process to create conductive paths on each molding compound layer of the semiconductor package.

Disclosed are semiconductor packages and methods of fabricating the same. The semiconductor package comprises a redistribution substrate including dielectric and redistribution patterns, a first substrate pad on the redistribution substrate and penetrating the dielectric pattern to be coupled to the redistribution pattern, a second substrate pad the redistribution substrate and spaced apart from the first substrate pad, a semiconductor chip on the redistribution substrate, a first connection terminal connecting the first substrate pad to one of chip pads of the semiconductor chip, and a second connection terminal connecting the second substrate pad to another one of the chip pads of the semiconductor chip. A top surface of the second substrate pad is located at a higher level than that of a top surface of the first substrate pad. A width of the second substrate pad is less than that of the first substrate pad.

A method for manufacturing a chip-mounting substrate includes a pre-coating step of forming a precoat on a substrate including a plurality of conductive portions and an insulating portion interposed between the conductive portions, an etching step of etching at least a portion of the precoat through a laser to form a pattern, and a step of forming a metal layer on the substrate. The pattern is disposed on at least one of the conductive portions, and the metal layer is formed in the pattern.

The deterioration of the resin base materials in the bonded structure is prevented. In a bonded structure containing two base materials at least one of which is a resin, an oxide which contains either P or Ag, V, and Te, and are formed by softening on the two base materials, bond the two base materials. In addition, in a method for producing a bonded structure containing two base materials at least one of which is a resin containing: supplying an oxide containing either P or Ag, V, and Te to the base material; and applying electromagnetic waves to the oxide, whereby the oxide, which soften on the substrates, bond the two base material.

A semiconductor package includes an interconnect component surrounded by a molding compound. The interconnect component comprises a first RDL structure. A second RDL structure is disposed on the interconnect component. A plurality of first connecting elements is disposed on the second RDL structure. A polish stop layer covers a surface of the interconnect component. A plurality of second connecting elements is disposed on and in the polish stop layer. At least one semiconductor die is mounted on the second connecting elements.

A semiconductor device package and method of manufacturing is provided. An interconnect pre-assembly includes a first frame having a plurality of first signal conduits affixed to a second frame having a plurality of second signal conduits embedded in a second substrate forming an electrical coupling between one or more first signal conduits and one or more of the second signal conduits. One or more conductive balls are connected to the one or more second signal conduits. The interconnect pre-assembly is placed over a semiconductor die, having at least one of the first conductive balls disposed over the semiconductor die. An encapsulant encapsulates the interconnect pre-assembly, the semiconductor die, and the one or more conductive balls, such that a portion of the one or more first conductive balls is exposed at a top surface of the encapsulant.

An air cavity package with one or more dovetail recesses configured with a first recess and a coincident second recess. The first recess has a first depth and the second recess has a second depth. The first recess has a lower width and an upper width smaller than the first lower width creating a dovetail shape. Individual dovetail recesses are created by creating a first recess in the flange at a first width and depth. A second recess with a second width and second depth and coincident with the first recess is pressed into the flange. The second width is greater than the first width and the second depth is smaller than the first depth. Pressing the second recess causes the first width at an upper portion to decrease, causing the first recess to develop a dovetail shape.

Disclosed herein are methods of fabricating a packaged radio-frequency (RF) device. The disclosed methods use a film during fabrication to control the distribution of an under-fill material between one or more components and a packaging substrate. The method includes mounting components to a first side of a packaging substrate and applying a film to a second side of a packaging substrate. The method also includes mounting a lower component to the second side of the packaging substrate and under-filling the lower component mounted on the second side of the packaging substrate with an under-filling agent. The method also includes removing the film on the second side of the packaging substrate and mounting solder balls to the second side of the packaging substrate after removal of the film.

A thermally enhanced semiconductor assembly with three dimensional integration includes a semiconductor chip electrically coupled to a wiring board by bonding wires. A heat spreader that provides an enhanced thermal characteristic for the semiconductor chip is disposed in a through opening of a wiring structure. Another wiring structure disposed on the heat spreader not only provides mechanical support, but also allows heat spreading and electrical grounding for the heat spreader by metallized vias. The bonding wires provide electrical connections between the semiconductor chip and the wiring board for interconnecting the semiconductor chip to terminal pads provided in the wiring board.