A semiconductor package and a manufacturing method thereof are provided. The semiconductor package includes first and second package components stacked upon and electrically connected to each other. The first package component includes first and second conductive bumps, the second package component includes third and fourth conductive bumps, and dimensions of the first and second conductive bumps are less than those of the third and fourth conductive bumps. The semiconductor package includes a first joint structure partially wrapping the first conductive bump and the third conductive bump, and a second joint structure partially wrapping the second conductive bump and the fourth conductive bump. A curvature of the first joint structure is different from a curvature of the second joint structure.

An integrated circuit (IC) chip comprises a plurality of pads and a plurality of bumps. The plurality of pads includes a first pad. The plurality of bumps is disposed on the plurality of pads. The plurality of bumps includes a first bump disposed on the first pad. The first bump as a width that is different than an exposed with of the first pad. The center of the first bump is not aligned with a center of the first pad.

An integrated circuit package substrate (ICPS) system includes a die including a first array of connectors and a substrate including a second array of connectors that is configured to be thermocompression bonded to the first array of connectors at a bonding temperature that is above a solder melting temperature. The first die is bonded to the substrate such that the first die is asymmetric with respect to a substrate center, and the second array of connectors is adjusted, at an alignment temperature that is below the solder melting temperature, for thermal expansion to the bonding temperature with respect to a reference point that is not a first die center.

A method for manufacturing a display panel includes providing a backplate, forming bonding parts on backplate, forming an auxiliary layer on backplate, releasing light-emitting elements onto the auxiliary layer such that electrodes of the light-emitting elements are in contact with the first parts to form an intermediate backplate, arranging the intermediate backplate under first predetermined condition under which a fluidity of the first part is greater than that of the second part, and bonding the electrodes and the bonding parts to form an eutectic bonding layer, and arranging the intermediate backplate under second predetermined condition such that the first and second parts form solid-state first and second members. The backplate includes first and second regions. The bonding parts are located in the first regions. The auxiliary layer covers the backplate and the bonding parts. The auxiliary layer includes first and second parts respectively located in the first and second regions.

A semiconductor device assembly includes a die stack, a plurality of thermoset regions, and underfill material. The die stack includes at least first and second dies that each have a plurality of conductive interconnect elements on upper surfaces. A portion of the interconnect elements are connected to through-silicon vias that extend between the upper surfaces and lower surfaces of the associated dies. The plurality of thermoset regions each comprise a thin layer of thermoset material extending from the lower surface of the second die to the upper surface of the first die, and are laterally-spaced and discrete from each other. Each of the thermoset regions extends to fill an area between a plurality of adjacent interconnect elements of the first die. The underfill material fills remaining open areas between the interconnect elements of the first die.

A semiconductor die (“die”) employing repurposed seed layer for forming additional signal paths to a back end-of-line (BEOL) structure of the die, and related integrated circuit (IC) packages and fabrication methods. A seed layer is repurposed that was disposed adjacent the BEOL interconnect structure to couple an under bump metallization (UBM) interconnect without a coupled interconnect bump thus forming an unraised interconnect bump, to a UBM interconnect that has a raised interconnect bump. To couple the unraised interconnect bump to the raised interconnect bump, the seed layer is selectively removed during fabrication to leave a portion of the seed layer repurposed that couples the UBM interconnect that does not have an interconnect bump to the UBM interconnect that has a raised interconnect bump. Additional routing paths can be provided between raised interconnect bumps to the BEOL interconnect structure through coupling of UBM interconnects to an unraised interconnect bump.

Disclosed are integrated circuit structures with interconnects of small size, also referred to micro-bumps. As pitches of micro-bumps become smaller, their sizes also become small. This makes it difficult to probe the integrated circuit structure to verify their operations. To enable probing, test pads of larger pitches are provided. The test pads, usually formed of metal, may be protected with solder caps.

A semiconductor package and a manufacturing method thereof are provided. The semiconductor package includes first and second package components stacked upon and electrically connected to each other. The first package component includes first and second conductive bumps, the second package component includes third and fourth conductive bumps, and dimensions of the first and second conductive bumps are less than those of the third and fourth conductive bumps. The semiconductor package includes a first joint structure partially wrapping the first conductive bump and the third conductive bump, and a second joint structure partially wrapping the second conductive bump and the fourth conductive bump. A curvature of the first joint structure is different from a curvature of the second joint structure.

An apparatus is provided which comprises: a plurality of first conductive contacts having a first pitch spacing on a substrate surface, a plurality of second conductive contacts having a second pitch spacing on the substrate surface, and a plurality of conductive interconnects disposed within the substrate to couple a first grouping of the plurality of second conductive contacts associated with a first die site with a first grouping of the plurality of second conductive contacts associated with a second die site and to couple a second grouping of the plurality of second conductive contacts associated with the first die site with a second grouping of the plurality of second conductive contacts associated with the second die site, wherein the conductive interconnects to couple the first groupings are present in a layer of the substrate above the conductive interconnects to couple the second groupings. Other embodiments are also disclosed and claimed.

Millimeter wave (mmWave) technology, apparatuses, and methods that relate to transceivers, receivers, and antenna structures for wireless communications are described. The various aspects include co-located millimeter wave (mmWave) and near-field communication (NFC) antennas, scalable phased array radio transceiver architecture (SPARTA), phased array distributed communication system with MIMO support and phase noise synchronization over a single coax cable, communicating RF signals over cable (RFoC) in a distributed phased array communication system, clock noise leakage reduction, IF-to-RF companion chip for backwards and forwards compatibility and modularity, on-package matching networks, 5G scalable receiver (Rx) architecture, among others.