A semiconductor package may include: a first semiconductor chip; a second semiconductor chip disposed over the first semiconductor chip; and a bump structure interposed between the first semiconductor chip and the second semiconductor chip to connect the first semiconductor chip and the second semiconductor chip, wherein the bump structure includes a core portion and a shell portion, the shell portion surrounding all side ails of the core portion, and wherein the shell portion has a higher melting point than the core portion.

An apparatus includes an Integrated Circuit (IC). A first pillar includes a first end and a second end. The first end is connected to the IC and the second end includes a first attachment point collinear with a first central axis of the first pillar. The first attachment point includes a first solder volume capacity. A second pillar includes a third end and a fourth end. The third end is connected to the IC and the fourth end includes a second attachment point disposed on a side of the second pillar facing the first pillar. The second attachment point includes a second solder volume capacity being less than the first solder volume capacity. A first distance between the first end and the second end is less than a second distance between the third end and the fourth end.

A sensor array and a read-out circuit are prepared. The sensor array and the read-out circuit are aligned such that each first electrode and each second electrode face each other in a state where a connection material is disposed between a second area of the sensor array and a fourth area of the read-out circuit. The read-out circuit is pressed against the sensor array with a first load such that the sensor array and the readout circuit are bonded by the connection material with a gap provided between each first electrode and each second electrode. The read-out circuit is pressed against the sensor array with a second load larger than the first load so that each first electrode and each second electrode are connected. Before the pressing with the second load, either one of the first electrode and the second electrode has a conical shape.

Disclosed embodiments include an integrated circuit (IC) comprising a silicon wafer, first and second conductive lines on the silicon wafer. There are first, second and third insulation blocks with portions on the first and second conductive lines and the silicon wafer, a metal pillar on the surface of the first conductive line opposite the silicon wafer, and a conductive adhesive block on the surface of the second conductive line opposite the silicon wafer. The IC also has a lead frame having first and second leads, and a capacitor having first and second capacitor terminals in which the first capacitor terminal is connected to the second lead using conductive adhesive, the second capacitor terminal is connected to the second conductive line through the conductive adhesive block, and the first lead is coupled to the first conductive line.

A direct bonded heterogeneous integration (DBHi) device includes a substrate including a trench formed in a top surface of the substrate. The DBHi device further includes a first chip coupled to the substrate on a first side of the trench by a plurality of first interconnects. The DBHi device further includes a second chip coupled to the substrate on a second side of the trench by a plurality of second interconnects. The second side of the trench is arranged opposite the first side of the trench. The DBHi device further includes a bridge coupled to the first chip and to the second chip by a plurality of third interconnects such that the bridge is suspended in the trench. The DBHi device further includes a non-conductive paste material surrounding the plurality of third interconnects to further couple the bridge to the first chip and to the second chip.

Provided is a ceramic laminated substrate which is formed on an electronic component to be mounted and is less likely to cause mounting defects even if there is irregularity in the height of solders. The ceramic laminated substrate includes: a ceramic laminate on which ceramic layers are laminated; via conductors; terminal electrodes; and a land electrode. The land electrode has a first land electrode and a second land electrode that are used to join different terminal electrodes of a single electronic component. The area of the first land electrode is smaller than the area of the second land electrode, and the first land electrode has a bump electrode and a plating layer, the second land electrode has a membrane electrode and plating layers, and the height of the first land electrode is formed higher than the height of the second land electrode.

Provided is a method for manufacturing a semiconductor package, the method including providing a semiconductor chip on a substrate, providing a bonding member between the substrate and the semiconductor chip, and bonding the semiconductor chip on the substrate by irradiating of a laser on the substrate. Here, the bonding member may include a thermosetting resin, a curing agent, and a laser absorbing agent.

Provided is a ceramic laminated substrate which is formed on an electronic component to be mounted and is less likely to cause mounting defects even if there is irregularity in the height of solders. The ceramic laminated substrate includes: a ceramic laminate on which ceramic layers are laminated; via conductors; terminal electrodes; and a land electrode. The land electrode has a first land electrode and a second land electrode that are used to join different terminal electrodes of a single electronic component. The area of the first land electrode is smaller than the area of the second land electrode, and the first land electrode has a bump electrode and a plating layer, the second land electrode has a membrane electrode and plating layers, and the height of the first land electrode is formed higher than the height of the second land electrode.

A method of manufacturing a semiconductor package includes estimating an error in a solder ball attaching process, determining a specification of a ball tool and a method of the solder ball attaching process, based on the estimated error, manufacturing the ball tool according to the determined specification thereof, and performing the solder ball attaching process based on the method of the solder ball attaching process. The determining of the specification of the ball tool and the method of the solder ball attaching process includes determining a number of a plurality of holders in the ball tool and a position and a width of each of the plurality of holders, determining a number of a plurality of working regions of a substrate and a position and a width of each of the plurality of working regions, and dividing a substrate into the plurality of working regions.

A semiconductor package including a molded power delivery module arranged between a package substrate and a semiconductor chip and including a plurality of input conductive structures and a plurality of reference conductive structures, wherein the input conductive structures alternate between the plurality of reference conductive structures, wherein the input conductive structure is electrically coupled with a chip input voltage terminal and a package input voltage terminal, wherein each of the plurality of reference conductive structures are electrically coupled with a semiconductor chip reference terminal and a package reference terminal.