A die including a first contact with a first shape (e.g., ring-shaped) and a second contact with a second shape (e.g., cylindrical shaped) different from the first shape. The first contact has an opening that extends through a central region of a surface of the first contact. A first solder portion is coupled to the surface of the first contact and the first solder portion has the first shape. A second solder portion is coupled to a surface of the second contact and the second solder portion has the second shape. The first solder portion and the second solder portion both have respective points furthest away from a substrate of the die. These respective points of the first solder portion and the second solder portion are co-planar with each other such that a standoff height of the die remains consistent when coupled to a PCB or an electronic component.

A structure and method for performing metal-to-metal bonding in an electrical device. For example and without limitation, various aspects of this disclosure provide a structure and method that utilize an interlocking structure configured to enhance metal-to-metal bonding.

An inductor conductor design which minimizes the impact of skin effect in the conductors at high frequencies in integrated circuits and the method of manufacture thereof is described herein.

A structure and method for performing metal-to-metal bonding in an electrical device. For example and without limitation, various aspects of this disclosure provide a structure and method that utilize an interlocking structure configured to enhance metal-to-metal bonding.

A semiconductor device of the ball grid array (BGA) type, the device having an electrode, and a process of forming the electrode are disclosed. The electrode includes an insulating film, a seed layer on the insulating film, a mound metal on the insulating film and an interconnection on the seed layer. The mound metal surrounds the seed layer without forming any gap therebetween. The interconnection, which is formed by electroless plating, is apart from the insulating film with the mound metal as an extension barrier for the plating.

Packaged microelectronic devices and methods for manufacturing packaged microelectronic devices are disclosed. In one embodiment, a system comprises a semiconductor component including an interposer substrate, a microelectronic die over the interposer substrate, and a connection structure composed of a volume of solder material between the interposer substrate and the microelectronic die. The connection structure can include at least one of (a) a single, unitary structure covering approximately all of the back side of the microelectronic die, and (b) a structure electrically isolated from internal active features of the microelectronic die. In some embodiments, the connection structure can be positioned to provide generally consistent stress distribution within the system.

In some forms, an electronic assembly includes a substrate; and a ball pad mounted on the substrate, wherein the ball pad includes a plurality of lobes projecting distally from a center of the ball pad. In some forms, he electronic assembly includes a substrate; and a ball pad mounted on the substrate, wherein the ball pad includes a lobe projecting distally from a center of the ball pad. In some forms, the electronic assembly includes a substrate; and a ball pad mounted on the substrate, wherein the ball pad includes at least one lobe projecting distally from a center of the ball pad; and an electronic package that includes at least one conductor that electrically connects the ball pad on the substrate to the electronic package.

Packaged microelectronic devices and methods for manufacturing packaged microelectronic devices are disclosed. In one embodiment, a system comprises a semiconductor component including an interposer substrate, a microelectronic die over the interposer substrate, and a connection structure composed of a volume of solder material between the interposer substrate and the microelectronic die. The connection structure can include at least one of (a) a single, unitary structure covering approximately all of the back side of the microelectronic die, and (b) a structure electrically isolated from internal active features of the microelectronic die. In some embodiments, the connection structure can be positioned to provide generally consistent stress distribution within the system.

A conductive bump assembly may include a passive substrate. The conductive bump assembly may also include a conductive bump pad supported by the passive substrate and surrounded by a first passivation layer opening. The conductive bump assembly may further include a second passivation layer opening on the passive substrate. The second passivation layer opening may be merged with the first passivation layer opening surrounding the conductive bump pad proximate an edge of the passive substrate. The conductive bump assembly may also include a conductive bump on the conductive bump pad.

In some embodiments, to increase the height-to-pitch ratio of a solder connection that connects different structures with one or more solder balls, only a portion of a solder ball's surface is melted when the connection is formed on one structure and/or when the connection is being attached to another structure. In some embodiments, non-solder balls are joined by an intermediate solder ball (140i). A solder connection may be surrounded by a solder locking layer (1210) and may be recessed in a hole (1230) in that layer. Other features are also provided.