A semiconductor package structure includes a base material, at least one semiconductor chip, an encapsulant, a depression structure, a redistribution layer and at least one conductive via. The semiconductor chip is disposed on the base material. The encapsulant is disposed on the base material and covers the at least one semiconductor chip. The encapsulant has an outer side surface. The depression structure is disposed adjacent to and exposed from of the outer side surface the encapsulant. The redistribution layer is disposed on the encapsulant. The conductive via is disposed in the encapsulant and electrically connects the semiconductor chip and the redistribution layer.

A semiconductor package including a semiconductor chip having a chip pad thereon; a first insulating layer; a redistribution line pattern on the first insulating layer; a redistribution via pattern through the first insulating layer to connect the chip pad to the redistribution line pattern; a second insulating layer covering the redistribution line pattern and including a first part having a first thickness and a second part having a second thickness. the second part being inward relative to the first part; a first conductive pillar through the first part and connected to the redistribution line pattern; a second conductive pillar through the second part and connected to the redistribution line pattern; a first connection pad on the first conductive pillar; a second connection pad on the second conductive pillar; a first connection terminal contacting the first connection pad; and a second connection terminal contacting the second connection pad.

A semiconductor device package includes an electronic component, a first passivation layer having an inner surface surrounding the electronic component, and a conductive layer disposed on the inner surface of the first passivation layer. The electronic component has a first surface, a second surface opposite the first surface, and a lateral surface extended between the first surface and the second surface. The conductive layer has a relatively rough surface. A method of manufacturing a semiconductor device package is also disclosed.

Packaging structure and method for forming a packaging structure are provided. A bonding layer is formed on the substrate. An improvement layer is formed on the bonding layer. The improvement layer contains openings exposing surface portions of the bonding layer at bottoms of the openings. Chips are provided and include functional surfaces. The chips are mounted on the substrate by bonding the functional surfaces of the chips to the bonding layer through the openings. Top surfaces of the chips are lower than or flush with a top surface of the improvement layer.

An apparatus is provided which comprises: a first die having a first surface and a second surface, the first die comprising: a first layer formed on the first surface of the first die, and a second layer formed on the second surface of the first die; a second die coupled to the first layer; and a plurality of structures to couple the apparatus to an external component, wherein the plurality of structures is coupled to the second layer.

Insulating layers of a redistribution layer of a semiconductor package may be formed as a polymer film having inorganic fillers formed therein. The inorganic fillers may trap reactive materials to inhibit and/or substantially prevent the metal conductors, such as chip pads of the semiconductor chip being packaged, from being damaged by the reactive material. As a result, the reliability and the durability of the semiconductor package may be improved.

In an embodiment a method for manufacturing a printed circuit board with at least one optoelectronic component integrated into the printed circuit board includes arranging the at least one optoelectronic component on a first metal layer, pressing a first electrically insulating layer onto the at least one optoelectronic component and creating at least one recess in the first metal layer and/or the first electrically insulating layer thereby at least partially exposing the at least one optoelectronic component, wherein the first electrically insulating layer comprises a fiber reinforced plastic or a glass fiber fabric.

A printable electronic component includes a component substrate and a circuit disposed in or on the component substrate. One or more electrically conductive connection posts protrude from the component substrate. One or more electrically conductive component contact pads are exposed on or over the component substrate on a side of the component substrate opposite the one or more connection posts. The one or more component contact pads and the one or more electrically conductive connection posts are both electrically connected to the circuit. The components can be printed onto a destination substrate and electrically connected to contact pads on the destination substrate through the connection posts. The components can also be printed onto other components and electrically connected through the connection posts and component contact pads to form a three-dimensional electronic structure.

A semiconductor device has a first semiconductor die mounted over a carrier. An interposer frame has an opening in the interposer frame and a plurality of conductive pillars formed over the interposer frame. The interposer is mounted over the carrier and first die with the conductive pillars disposed around the die. A cavity can be formed in the interposer frame to contain a portion of the first die. An encapsulant is deposited through the opening in the interposer frame over the carrier and first die. Alternatively, the encapsulant is deposited over the carrier and first die and the interposer frame is pressed against the encapsulant. Excess encapsulant exits through the opening in the interposer frame. The carrier is removed. An interconnect structure is formed over the encapsulant and first die. A second semiconductor die can be mounted over the first die or over the interposer frame.

Disclosed are a packaging substrate and a semiconductor device. The semiconductor device includes an element unit including a semiconductor element and a packaging substrate electrically connected to the element unit. By applying a glass substrate to the packaging substrate as a core substrate, connecting the semiconductor element and a motherboard can be closer to each other, so that electrical signals are transferred through as short a path, and significantly improved electrical properties such as a signal transfer rate could be achieved. Also, it is possible to prevent an occurrence of a parasitic element effect and to apply to a high-speed circuit device without additional insulating process.