Abstract: The present invention provides a package structure and fabrication method thereof. The method includes providing a first carrier having a metal layer; forming a dielectric layer on the metal layer; forming a plurality of conductive pillars embedded into the dielectric layer and protruding from a surface of the dielectric layer, and disposing an electronic component on the surface of the dielectric layer; forming an encapsulating layer on the dielectric layer to encompass the plurality of conductive pillars, the dielectric layer and the electronic component; removing a portion of the encapsulating layer and the first carrier such that two ends of each of the plurality of conductive pillars are exposed from the encapsulating layer and the dielectric layer. Therefore, the present invention effectively reduces manufacturing costs and the need for an opening process while manufacturing the conductive pillars can be eliminated.

Abstract: A package structure is provided, which includes: a chip carrier having a plurality of conductive connection portions; at least an electronic element disposed on the chip carrier; a plurality of conductive wires erectly positioned on the conductive connection portions, respectively; an encapsulant formed on the chip carrier for encapsulating the conductive wires and the electronic element, wherein one ends of the conductive wires are exposed from the encapsulant; and a circuit layer formed on the encapsulant and electrically connected to exposed ends of the conductive wires. According to the present invention, the conductive wires serve as an interconnection structure. Since the wire diameter of the conductive wires is small and the pitch between the conductive wires can be minimized, the present invention reduces the size of the chip carrier and meets the miniaturization requirement.

Abstract: A semiconductor package is provided, including a semiconductor substrate having a plurality of conductive vias, a buffer layer formed on the semiconductor substrate, a plurality of conductive pads formed on end surfaces of the conductive vias and covering the buffer layer. During a reflow process, the buffer layer greatly reduces the thermal stress, thereby eliminating the occurance of cracking at the interface of conductive pads. A method of fabricating such a semiconductor package is also provided.

Abstract: The present invention provides a semiconductor package and a method of fabricating the same, including: placing in a groove of a carrier a semiconductor element having opposing active and non-active surfaces, and side surfaces abutting the active surface and the non-active surface; applying an adhesive material in the groove and around a periphery of the side surfaces of the semiconductor element; forming a dielectric layer on the adhesive material and the active surface of the semiconductor element; forming on the dielectric layer a circuit layer electrically connected to the semiconductor element; and removing a first portion of the carrier below the groove to keep a second portion of the carrier on a side wall of the groove intact for the second portion to function as a supporting member. The present invention does not require formation of a silicon interposer, and therefore the overall cost of a final product is much reduced.

Abstract: The present invention provides a semiconductor package and a method of fabricating the same, including: placing a semiconductor element in a groove of a carrier; forming a dielectric layer on the semiconductor element; forming on the dielectric layer a circuit layer electrically connected to the semiconductor element; and removing a first portion of the carrier below the groove to keep a second of the carrier on a sidewall of the groove intact for the second portion to function as a supporting part. The present invention does not require formation of a silicon interposer, therefore the overall cost of the final product is much reduced.

Abstract: A stacked package module is disclosed, which comprises: a first package structure comprising a first circuit board with a first chip embedded therein, wherein the first chip has a plurality of electrode pads; the first circuit board comprises a first surface, an opposite second surface, a plurality of exposed electro-connecting ends, a plurality of first conductive pads on the first surface, a plurality of conductive vias, and at least one circuit layer, therewith the electrode pads of the first chip electrically connecting to the electro-connecting ends and the first conductive pads directly through the conductive vias and the circuit layer; and a second package structure electrically connecting to the first package structure through a plurality of first solder balls to make a package on package. The stacked package module of this invention has characters of compact size, high performance, high flexibility, and detachability.

Abstract: Provided is a packaging substrate with a heat-dissipating structure, including a core layer with a first surface and an opposite second surface having a first metal layer and a second metal layer respectively. Portions of the first metal layer are exposed from a second cavity penetrating the core layer and second metal layer. Portions of the second metal layer are exposed from a first cavity penetrating the core layer and first metal layer. Semiconductor chips each having an active surface with electrode pads thereon and an opposite inactive surface are received in the first and second cavities and attached to the second metal layer and the first metal layer respectively. Conductive vias disposed in build-up circuit structures electrically connect to the electrode pads of the semiconductor chips. A heat-dissipating through hole penetrating the core layer and build-up circuit structures connects the metal layers and contact pads.

Abstract: Provided is a packaging substrate with a heat-dissipating structure, including a core layer with a first surface and an opposite second surface having a first metal layer and a second metal layer respectively. Portions of the first metal layer are exposed from a second cavity penetrating the core layer and second metal layer. Portions of the second metal layer are exposed from a first cavity penetrating the core layer and first metal layer. Semiconductor chips each having an active surface with electrode pads thereon and an opposite inactive surface are received in the first and second cavities and attached to the second metal layer and the first metal layer respectively. Conductive vias disposed in build-up circuit structures electrically connect to the electrode pads of the semiconductor chips. A heat-dissipating through hole penetrating the core layer and build-up circuit structures connects the metal layers and contact pads.

Abstract: A stacked package module is disclosed, which comprises: a first package structure comprising a first circuit board with a first chip embedded therein, wherein the first chip has a plurality of electrode pads; the first circuit board comprises a first surface, an opposite second surface, a plurality of exposed electro-connecting ends, a plurality of first conductive pads on the first surface, a plurality of conductive vias, and at least one circuit layer, therewith the electrode pads of the first chip electrically connecting to the electro-connecting ends and the first conductive pads directly through the conductive vias and the circuit layer; and a second package structure electrically connecting to the first package structure through a plurality of first solder balls to make a package on package. The stacked package module of this invention has characters of compact size, high performance, high flexibility, and detachability.

Abstract: A stacked package module is disclosed, which comprises: a first package structure comprising a first circuit board with a first chip embedded therein, wherein the first chip has a plurality of electrode pads, the first circuit board comprises a first surface, an opposite second surface, a plurality of first conductive pads on the first surface, a plurality of second conductive pads on the second surface, a plurality of conductive vias, and at least one circuit layer, and the electrodes of the first chip directly electrically connect to the conductive pads on the surfaces of the circuit board through the conductive vias and the circuit layer within the circuit board; and a second package structure electrically connecting to the first package structure through a plurality of solder balls to make package on package. The stacked package module provided by this invention has characteristics of compact size, high performance, and high flexibility.