A method of manufacturing a semiconductor package includes: forming via holes through an insulating layer to expose a redistribution conductor; forming a preliminary seed layer extending along the insulating layer and an inner surface of the via holes; forming a first photoresist layer on the preliminary seed layer which exposes first partial surfaces of the preliminary seed layer within the via holes; forming under-bump metal (UBM) vias in the via holes; forming a second photoresist layer by removing a partial region of the first photoresist layer; forming UBM pads covering the UBM vias and the second partial surfaces of the preliminary seed layer, each of the UBM pads has a convex surface protruding on a side facing away from a corresponding one of the UBM vias; removing the second photoresist layer and a partial region of the preliminary seed layer; and attaching a solder ball on the UBM pads.

A method of manufacturing a semiconductor device is provided. The method includes forming a redistribution layer (RDL) over a semiconductor die, a portion of the RDL contacting a die pad of the semiconductor die. A non-conductive layer is formed over the RDL. An opening in the non-conductive layer is formed exposing a portion of the RDL. A plurality of plateau regions is formed in the non-conductive layer. A cavity region in the non-conductive layer separates each plateau region of the plurality of plateau regions. A metal layer is deposited over the non-conductive layer and exposed portion of the RDL and etched to expose the plurality of plateau regions through the metal layer. The cavity region remains substantially filled by a portion of the metal layer.

An interposer substrate is provided between a mounting substrate and a semiconductor device. The interposer substrate includes a conductor electrically connecting the mounting substrate and the electronic device; a mechanical member electrically insulated from the mounting substrate, the semiconductor device, and the conductor; and a first resin material provided around the conductor and the mechanical member, wherein the mechanical member has a Young's modulus higher than that of the first resin material.

The present invention relates to the field of photonic integrated circuits and provides a semiconductor device and a manufacturing method thereof. The semiconductor device includes an EIC chip and a PIC chip arranged on a substrate, the EIC chip is located between the PIC chip and the substrate. In embodiments, at least one EIC chip is disposed on a surface of a single PIC chip facing the substrate, and the EIC chip is mounted on the substrate through a connection structure. Therefore, the wiring of the PIC chip in the semiconductor device of the present invention is optimized such that the voltage drop due to long wiring distance can be suppressed, and the package structure of the semiconductor device is also optimized.

An IC package includes one or more microelectronic devices, a plurality of package bumps disposed at a first side, and a metal structure electrically connecting at least a first device contact pad of a first microelectronic device and at least a first package bump of the plurality of package bumps. The metal structure includes an RDL trace extending between a first region aligned with the first device contact pad and a second region aligned with the first package bump, wherein the first package bump is mechanically and electrically connected directly to the second region of the RDL trace. The metal structure further includes a first via extending between the first region of the RDL trace and the first device contact pad and further includes a set of one or more support studs extending from the second region to a support surface facing the first side.

A chip package and method for fabricating the same are provided that includes embedded off-die inductors coupled in series. One of the off-die inductors is disposed in a redistribution layer formed on a bottom surface of an integrated circuit (IC) die. The other of the series connected off-die inductors is disposed in a substrate of the chip package. The substrate may be either an interposer or a package substrate.

An integrated circuit die includes a semiconductor substrate, an interconnect layer including bonding pads, and a passivation layer covering the interconnect layer and including openings at the bonding pads. A conductive redistribution layer including conductive lines and conductive vias is supported by the passivation layer. An insulating layer covers the conductive redistribution layer and the passivation layer. Channels formed in an upper surface of the insulating layer delimit pedestal regions in the insulating layer. A through via extends from an upper surface of each pedestal region through the pedestal region and the insulating layer to reach and make contact with a portion of the conductive redistribution layer. A metal pad is formed at the upper surface of each pedestal region in contact with its associated through via. The metal pads for leads of a quad-flat no-lead (QFN) type package.