A package structure includes at least one integrated circuit component, an insulating encapsulation, and a redistribution structure. The at least one integrated circuit component includes a semiconductor substrate, an interconnection structure disposed on the semiconductor substrate, and signal terminals and power terminals located on and electrically connecting to the interconnection structure. The interconnection structure is located between the semiconductor substrate and the signal terminals and between the semiconductor substrate and the power terminals, and where a size of the signal terminals is less than a size of the power terminals. The insulating encapsulation encapsulates the at least one integrated circuit component. The redistribution structure is located on the insulating encapsulation and electrically connected to the at least one integrated circuit component.

A package structure includes at least one integrated circuit component, an insulating encapsulation, and a redistribution structure. The at least one integrated circuit component includes a semiconductor substrate, an interconnection structure disposed on the semiconductor substrate, and signal terminals and power terminals located on and electrically connecting to the interconnection structure. The interconnection structure is located between the semiconductor substrate and the signal terminals and between the semiconductor substrate and the power terminals, and where a size of the signal terminals is less than a size of the power terminals. The insulating encapsulation encapsulates the at least one integrated circuit component. The redistribution structure is located on the insulating encapsulation and electrically connected to the at least one integrated circuit component.

The invention relates to a method for producing a solder connection between a plurality of components (12A, 12B) in a process chamber (74) sealed off from its surroundings by heating and melting solder material (16) which is arranged between the components (12A, 12B) to be connected. It is proposed that the components (12A, 12B) to be connected are provisionally connected with a bonding material (18) to form a solder group (10) in which the components (12A, 12B) are fixed relative to one another in a joining position.

A semiconductor structure includes a first substrate; a second substrate, disposed over the first substrate; a die, disposed over the second substrate; a via, extending through the second substrate and electrically connecting to the die; a redistribution layer (RDL) disposed between the first substrate and the second substrate, including a dielectric layer, a first conductive structure electrically connecting to the via, and a second conductive structure laterally surrounding the first conductive structure; and an underfill material, partially surrounding the RDL, wherein one end of the second conductive structure exposed through the dielectric layer is entirely in contact with the underfill material.

A semiconductor package including a semiconductor chip, a redistribution layer structure disposed under the semiconductor chip, a bump pad disposed under the redistribution layer structure and having an upper structure of a first width and a lower structure of a second width less than the first width, a metal seed layer disposed along a lower surface of the upper structure and a side surface of the lower structure, an insulating layer surrounding the redistribution layer structure and the bump pad, and a bump structure disposed under the bump pad. A first undercut is disposed at one end of the metal seed layer that contacts the upper structure, and a second undercut is disposed at an other end of the metal seed layer that contacts the lower structure.

A semiconductor package including a semiconductor chip, a redistribution layer structure disposed under the semiconductor chip, a bump pad disposed under the redistribution layer structure and having an upper structure of a first width and a lower structure of a second width less than the first width, a metal seed layer disposed along a lower surface of the upper structure and a side surface of the lower structure, an insulating layer surrounding the redistribution layer structure and the bump pad, and a bump structure disposed under the bump pad. A first undercut is disposed at one end of the metal seed layer that contacts the upper structure, and a second undercut is disposed at an other end of the metal seed layer that contacts the lower structure.

An integrated circuit chip is attached to a support that includes first conductive elements. First conductive pads are located on the integrated circuit chip and are electrically coupled to the first conductive elements by conductive wires. The integrated circuit chip further includes a conductive track. A switch circuit is provided to selectively electrically connect each first conductive pad to the conductive track. To test the conductive wires, a group of first conductive pads are connected by their respective switch circuits to the conductive track and current flow between corresponding first conductive elements is measured.

An integrated circuit chip is attached to a support that includes first conductive elements. First conductive pads are located on the integrated circuit chip and are electrically coupled to the first conductive elements by conductive wires. The integrated circuit chip further includes a conductive track. A switch circuit is provided to selectively electrically connect each first conductive pad to the conductive track. To test the conductive wires, a group of first conductive pads are connected by their respective switch circuits to the conductive track and current flow between corresponding first conductive elements is measured.

One embodiment includes partially forming a first through via in a substrate of an interposer, the first through via extending into a first side of the substrate of the interposer. The method also includes bonding a first die to the first side of the substrate of the interposer. The method also includes recessing a second side of the substrate of the interposer to expose the first through via, the first through via protruding from the second side of the substrate of the interposer, where after the recessing, the substrate of the interposer is less than 50 μm thick. The method also includes and forming a first set of conductive bumps on the second side of the substrate of the interposer, at least one of the first set of conductive bumps being electrically coupled to the exposed first through via.

One embodiment includes partially forming a first through via in a substrate of an interposer, the first through via extending into a first side of the substrate of the interposer. The method also includes bonding a first die to the first side of the substrate of the interposer. The method also includes recessing a second side of the substrate of the interposer to expose the first through via, the first through via protruding from the second side of the substrate of the interposer, where after the recessing, the substrate of the interposer is less than 50 μm thick. The method also includes and forming a first set of conductive bumps on the second side of the substrate of the interposer, at least one of the first set of conductive bumps being electrically coupled to the exposed first through via.