Abstract: A package structure and a package process are proposed in using pillar bumps to connect an upper second chip and through silicon vias of a lower first chip, wherein a gap between the first chip and the second chip can be controlled by adjusting a height of the pillar bumps. In other words, the pillar bumps compensate the height difference between the first chip and a molding compound surrounding the first chip so as to ensure the bondibility between the pillar bumps and the corresponding through silicon vias and improve the process yield. Furthermore, the pillar bumps maintain the gap between the second chip and the molding compound for allowing an underfill being properly filled into the space between the first chip and the second chip.

Abstract: A package process includes following steps. A circuit mother board comprising a plurality of circuit boards is disposed on a carrier. Semiconductor devices are provided, wherein each of the semiconductor devices has a top surface and a bottom surface opposite thereto. Each of the semiconductor devices has conductive vias each having a first end surface and a second end surface exposed by the bottom surface of the semiconductor device. The semiconductor devices are connected to the corresponding circuit boards through their conductive vias with their bottom surface facing the circuit mother board. An insulating paste is formed between each of the semiconductor devices and its corresponding circuit board. A protection layer is formed on the circuit mother board to cover the semiconductor devices. Then, the protection layer and the semiconductor devices are thinned to expose the first end surface of each of the conductive vias.

Abstract: A flip chip package structure including a chip, a carrier, and a plurality of bumps is provided. The chip has a bonding surface and a plurality of bump pads thereon. The carrier is disposed corresponding to the chip and includes a substrate and a plurality of pre-solders. The substrate has a carrying surface and a patterned trace layer thereon. The patterned trace layer has a plurality of traces, and each of the traces has an outward protruding bonding portion corresponding to the bump. The line width of the bonding portion is greater than that of the trace. The pre-solders are disposed on the bonding portions, respectively. The bumps are disposed between the bump pads and the corresponding pre-solders such that the chip is electrically connected to the carrier through the bumps.

Abstract: In one embodiment, a semiconductor device package includes: (1) a substrate unit; (2) connecting elements disposed adjacent to a periphery of the substrate unit and extending upwardly from an upper surface of the substrate unit; (3) a semiconductor device disposed adjacent to the upper surface of the substrate unit and electrically connected to the substrate unit; and (4) a package body disposed adjacent to the upper surface of the substrate unit and covering the semiconductor device. A lateral surface of the package body is substantially aligned with a lateral surface of the substrate unit. The package body defines openings that at least partially expose respective ones of the connecting elements. At least one of the connecting elements has a width WC, and at least one of the openings has a width WU adjacent to an upper surface of the package body, such that WU>WC.

Abstract: A chip package structure and process are provided; the structure includes a substrate, a chip, a solder layer and at least a stud bump. The substrate has at least a contact pad, and the chip has an active surface where at least a bonding pad is disposed. The stud bump is disposed on the bonding pad of the chip or on the contact pad of the substrate, and the stud bump joints with the solder layer to fix the chip on the substrate. The stud bump is made of gold-silver alloy containing silver below 15% by weight.

Abstract: A flip chip package structure including a chip, a carrier, and a plurality of bumps is provided. The chip has a bonding surface and a plurality of bump pads thereon. The carrier is disposed corresponding to the chip and includes a substrate and a plurality of pre-solders. The substrate has a carrying surface and a patterned trace layer thereon. The patterned trace layer has a plurality of traces, and each of the traces has an outward protruding bonding portion corresponding to the bump. The line width of the bonding portion is greater than that of the trace. The pre-solders are disposed on the bonding portions, respectively. The bumps are disposed between the bump pads and the corresponding pre-solders such that the chip is electrically connected to the carrier through the bumps.

Abstract: A stacked type chip package structure including a package structure, a corresponding substrate, and a number of second bumps is provided. The package structure includes a first chip, a second chip, a number of first bumps, and a first underfill. The first chip is disposed above the second chip. The first bumps are disposed between the first chip and the second chip for electrically connecting the first chip and the second chip. The first underfill is used to fill between the first chip and the second chip and encapsulates the first bumps. The package structure is disposed above the corresponding substrate in a reverse manner, such that the first chip is disposed between the second chip and the corresponding substrate. The second bumps are disposed between the second chip and the corresponding substrate, such that the second chip is electrically connected to the corresponding substrate through the second bumps.