A semiconductor laser component including a semiconductor chip arranged to emit laser radiation, a cladding that is electrically insulating and covers the semiconductor chip in places, and a bonding layer that electrically conductively connects the semiconductor chip to a first connection point, wherein the semiconductor chip includes a cover surface, a bottom surface, a first front surface, a second front surface, a first side surface and a second side surface, the first front surface is arranged to decouple the laser beam, the cladding covers the semiconductor chip at least in places on the cover surface, the second front surface, the first side surface and the second side surface, and the bonding layer on the cladding extends from the cover surface to the first connection point.

The present invention provides a packaging method and a packaging structure for a cascode power electronic device, in which a hetero-multiple chip scale package is used to replace the traditional die bonding and wire bonding packaging method. The cascode power electronic device can reduce the inductance resistance and thermal resistance of the connecting wires and reduce the size of the package; and increase the switching frequency of power density. The chip scale package of the present invention uses more than one gallium nitride semiconductor die, more than one diode, and more than one metal oxide semiconductor transistor. The package structure can use TO-220, quad flat package or other shapes and sizes; the encapsulation process of the traditional epoxy molding compounds can be used in low-power applications; and the encapsulation process of ceramic material can be used in high-power applications.

A package structure for a semiconductor device includes a first conductive layer, a second conductive layer, a first die, a second die, a plurality of first blind via pillars and a conductive structure. The first conductive layer has a first surface and a second surface. The first die and the second die respectively have an active surface and a back surface, which are disposed opposite to each other. There is a plurality of metal pads disposed on the active surface. The first die is attached to the first surface of the first conductive layer with its back surface, and the second die is attached to the second surface of the first conductive layer with its back surface. The first and second conductive layers, the first and second dies, the first blind hole pillars and conductive structure are covered by a dielectric material.

A method includes surrounding a die and a conductive pillar proximate the die with a molding material, where the die and the conductive pillar are disposed over a first side of a first redistribution structure, where a second side of the first redistribution structure opposing the first side is attached to a first carrier; bonding conductive pads disposed on a first surface of a pre-made second redistribution structure to the die and to the conductive pillar, where a second surface of the pre-made second redistribution structure opposing the first surface is attached to a second carrier; after bonding the conductive pads, removing the second carrier to expose conductive features of the pre-made second redistribution structure proximate the second surface; and forming conductive bumps over and electrically coupled to the conductive features of the pre-made second redistribution structure.

A package structure includes a semiconductor die, a redistribution circuit structure, and conductive pads. The redistribution circuit structure is located on and electrically connected to the semiconductor die, the redistribution circuit structure includes a first contact pad having a first width and a second contact pad having a second width. The conductive pads are located on and electrically connected to the redistribution circuit structure through connecting to the first contact pad and the second contact pad, the redistribution circuit structure is located between the conductive pads and the semiconductor die. The first width of the first contact pad is less than a width of the conductive pads, and the second width of the second contact pad is substantially equal to or greater than the width of the conductive pads.

A semiconductor package structure includes a first redistribution layer, a plurality of conductive connectors, a chip, and an encapsulant. The first redistribution layer has a first surface and a second surface opposite to the first surface. The first redistribution layer includes at least one conductive pattern and at least one dielectric layer stacked on each other. The conductive pattern includes a plurality of landing pads, and each of the landing pads is separated from the dielectric layer. The conductive connectors are located on the first surface. Each of the conductive connectors is corresponding to and electrically connected to one of the landing pads. The chip is located on the first surface. The chip is electrically connected to the first redistribution layer. The encapsulant encapsulates the chip and the conductive connectors. A manufacturing method of a semiconductor package structure is also provided.

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.

A semiconductor die is attached on a die mounting surface of a substrate. An insulating encapsulation of laser direct structuring (LDS) material is molded onto the substrate and the semiconductor die. The insulating encapsulation of LDS material has a front surface including a first portion and a second portion separated by gaps therebetween. Laser direct structuring processing is applied to the first portion of the front surface to structure in the encapsulation of LDS material electrically conductive formations including electrically conductive lines over the front surface and to the second portion of the front surface of the encapsulation of LDS material to form thereon a reinforcing warp-countering structure. The separation gaps are left exempt from laser direct structuring processing and the reinforcing warp-countering structure is electrically insulated from the electrically conductive lines by LDS material left exempt from laser direct structuring processing at the separation gaps.

A method includes thinning a semiconductor substrate of a device die to reveal through-substrate vias that extend into the semiconductor substrate, and forming a first redistribution structure, which includes forming a first plurality of dielectric layers over the semiconductor substrate, and forming a first plurality of redistribution lines in the first plurality of dielectric layers. The first plurality of redistribution lines are electrically connected to the through-substrate vias. The method further includes placing a first memory die over the first redistribution structure, and forming a first plurality of metal posts over the first redistribution structure. The first plurality of metal posts are electrically connected to the first plurality of redistribution lines. The first memory die is encapsulated in a first encapsulant. A second plurality of redistribution lines are formed over, and electrically connected to, the first plurality of metal posts and the first memory die.

An apparatus is described that includes a redistribution layer and a semiconductor die on the redistribution layer. An electrically conductive layer resides over the semiconductor die. A compound mold resides over the electrically conductive layer.