A three-dimensional fan-out integrated package structure, a packaging method thereof, and a wireless headset are disclosed. The three-dimensional fan-out integrated package structure includes a first rewiring layer, a second rewiring layer, a metal connection pillar, a first semiconductor chip, a second semiconductor chip, a first filler layer, a first encapsulating layer, a functional chip, a second filler layer, a second encapsulating layer, and metal bumps. By stacking two semiconductor chips, the structure can effectively reduce the packaging area and realize device packaging with high density and high integration, while enabling the minimum line width/line spacing to be reduced to 1.5 μm/1.5 μm. In addition, the three-dimensional fan-out integrated package structure can simultaneously integrate various functional chips and components such as GPU/PMU/DDR/mm-wave antenna/capacitor/inductor/transistor/flash memory/filter to realize system-level packaging, which not only can reduce cost but also improve the effectiveness of the package structure by using physical isolation to reduce device interference.

The present disclosure describes a process for making a three-dimensional (3D) package, which starts with providing a mold precursor module that includes a first device die and a floor connectivity die (FCD) encapsulated by a mold compound. The FCD includes a sacrificial die body and multiple floor interconnections underneath the sacrificial die body. Next, the mold compound is thinned down until the sacrificial die body of the FCD is completely consumed, such that each floor interconnection is exposed through the mold compound. The thinning down step does not affect a device layer in the first device die. A second device die, which includes a die body and multiple electrical die interconnections, is then mounted over the exposed floor interconnections. Herein, each electrical die interconnection is vertically aligned with and electrically connected to a corresponding floor interconnection from the FCD.

A manufacturing method of an electronic apparatus is provided, and the manufacturing method includes following steps. A substrate is provided. A plurality of first bonding pads are formed on the substrate. A plurality of electronic devices are provided, and each of the electronic devices includes at least one second bonding pad. The second bonding pads of the electronic devices corresponding to the first bonding pads are laminated onto the corresponding first bonding pads on the substrate, so as to bond the electronic devices to the substrate. The corresponding first and second bonding pads respectively have bonding surfaces with different surface topographies. The manufacturing method of the electronic apparatus is capable of reducing short circuit during a bonding process or improving a bonding yield.

Provided is a semiconductor package including a first bump pad on a first substrate, a second bump pad on a second substrate, a core material for reverse reflow between the first bump pad and the second bump pad, and a solder member forming a solder layer on the core material for reverse reflow. The solder member is in contact with the first bump pad and the second bump pad. Each of a first diameter of the first bump pad and a second diameter of the second bump pad is at least about 1.1 times greater than a third diameter of the core material for reverse reflow. The core material for reverse reflow includes a core, a first metal layer directly coated on the core, and a second metal layer directly coated on the first metal layer.

Deformable conductive contacts are provided. A plurality of deformable contacts on a first substrate may be joined to a plurality of conductive pads on a second substrate during die level or wafer level assembly of microelectronics. Each deformable contact complies to a degree that is related to the amount of joining pressure between the first substrate and the second substrate. Since an individual contact can make the conductive coupling within a range of distances from a target pad, an array of the deformable contacts provides tolerance and compliance when there is some variation in height of the conductive elements on either side of the join. A flowable underfill may be provided to press the deformable contacts against opposing pads and to permanently join the surfaces at a fixed distance. The deformable contacts may include a wiping feature to clear their target pads for establishing improved metal-to-metal contact or a thermocompression bond.

A wiring substrate includes a first insulating layer including a first through-hole formed through the first insulating layer in a thickness direction, a wiring layer formed on a lower surface of the first insulating layer, and a via wiring filled in the first through-hole and connected to the wiring layer, the via wiring having such a shape that it gradually becomes thinner from one side close to the lower surface of the first insulating layer toward the other side close to an upper surface of the first insulating layer, the via wiring including a first recess formed in an upper end surface of the via wiring. An upper end portion of the via wiring is an electrode pad for electric connection with an electronic component.

The present application discloses a semiconductor device. The semiconductor device includes a package structure including a first side and a second side opposite to the first side; an interposer structure positioned over the first side of the package structure; a first die positioned over the interposer structure; a second die positioned over the interposer structure; and a plurality of middle interconnectors positioned between the first side of the package structure and the first die and between the first side of the package structure and the second die. The plurality of middle interconnectors respectively includes a middle exterior layer positioned between the first side of the package structure and the interposer structure, a middle interior layer enclosed by the middle exterior layer, and a cavity enclosed by the interposer structure, the package structure, and the middle interior layer.

The present application discloses a semiconductor device. The semiconductor device includes a package structure including a first side and a second side opposite to the first side; an interposer structure positioned over the first side of the package structure; a first die positioned over the interposer structure; a second die positioned over the interposer structure; and a plurality of middle interconnectors positioned between the first side of the package structure and the first die and between the first side of the package structure and the second die. The plurality of middle interconnectors topographically aligned with the first die include a first density. The plurality of middle interconnectors topographically aligned with the second die include a second density different from the first density.

A processor-implemented method and integrated circuit package are provided. According to an implementation, a method of producing a chip package includes de-populating solder balls at selected locations in a fine pitch package, and providing test pads at the de-populated solder ball locations. In an example implementation, the method comprises receiving and modifying a package design. In an implementation, a row of test pads in an integrated circuit package is provided in a plurality of concentric annular rows, the row of test pads being adjacent an outer row of via-connected solder balls and adjacent an inner row of via-connected solder balls. In an implementation, test pads are located on a PCB-facing surface of the package at a subset of locations opposing at least one via position on a package-facing surface of the PCB. The test pads maintain a large number of signal pins and do not interfere with the via.

An example method for attaching a ball grid array chip to a circuit board includes providing an adapter for attaching a chip with a plurality of solder balls to a circuit board, the adapter having an adapter substrate made from a material having substantially the same coefficient of thermal expansion as the substrate used in the chip and having at least one electrical contact site on a mounting surface of the adapter substrate for engaging a solder ball on the ball grid array chip and a plurality of lead wires extending from each side of the adapter substrate. At least one of the lead wires is electrically connected to at least one electrical contact site on the adapter substrate.