Embodiments are directed to a method of forming a semiconductor chip package and resulting structures having a mixed under-bump metallization (UBM) size and pitch on a single die. A first set of UBMs having a first total plateable surface area is formed on a first region of a die. A second set of UBMs having an equal total plateable surface area is formed on a second region of the die. A solder bump having a calculated solder height is applied to a plateable surface of each UBM. The solder height is calculated such that a volume of solder in the first region is equal to a volume of solder in the second region.

Embodiments are directed to a method of forming a semiconductor chip package and resulting structures having a mixed under-bump metallization (UBM) size and pitch on a single die. A first set of UBMs having a first total plateable surface area is formed on a first region of a die. A second set of UBMs having an equal total plateable surface area is formed on a second region of the die. A solder bump having a calculated solder height is applied to a plateable surface of each UBM. The solder height is calculated such that a volume of solder in the first region is equal to a volume of solder in the second region.

A surface mounting semiconductor component includes a semiconductor device, a circuit board, a number of first solder bumps, and a number of second solder bumps. The semiconductor device included a number of die pads. The circuit board includes a number of contact pads. The first solder bumps are configured to bond the semiconductor device and the circuit board. Each of the first solder bumps connects at least two die pads with a corresponding contact pad. Each of the second solder bumps connects a die pad with a corresponding contact pad. A method of forming a surface mounting component or a chip scale package assembly wherein the component or assembly has at least two different types of solder bumps.

The invention relates to an electronic system comprising: an integrated circuit die having: at least 2 bond pads a redistribution layer, said redistribution layer having: at least a solder pad comprising 2 portions arranged to enable an electrical connection between each other by a same solder ball placed on said solder pad, but electrically isolated of each other in the absence of a solder ball on the solder pad at least 2 redistribution wires, each one connecting one of the 2 portions to one of the 2 bond pads,
a second bond pad connected via a second redistribution wire to a second portion of the solder pad being dedicated to testing said integrated circuit die a grounded printed circuit board track, a solder ball being placed between the solder pad and the printed circuit board track.

An integrated circuit die having at least two bond pads, a redistribution layer, the redistribution layer including at least one solder pad including comprising two portions arranged to enable an electrical connection between each other by a same solder ball placed on the solder pad, but electrically isolated of each other in the absence of a solder ball on the solder pad at least two redistribution wires, each one connecting one of the two portions to one of the two bond pads, a first bond pad connected via a first redistribution wire to a first portion of the solder pad being dedicated to digital ground and a second bond pad connected via a second redistribution wire to a second portion of the solder pad being dedicated to analog ground.

Various aspects of an approach for routing die signals in an interior portion of a die using external interconnects are described herein. The approach provides for contacts coupled to circuits in the interior portion of the die, where the contacts are exposed to an exterior portion of the die. The external interconnects are configured to couple these contacts so that signals from the circuits in the interior portion of the die may be routed externally to the die. In various aspects of the disclosed approach, the external interconnects are protected by a packaging for the die.

A semiconductor substrate is provided with an annular cavity extending from a front side of the substrate to an opposite rear side. A metallization is applied in the annular cavity, thereby forming a through-substrate via and leaving an opening of the annular cavity at the front side. A solder ball is placed above the opening and a reflow of the solder ball is effected, thereby forming a void of the through-substrate via, the void being covered by the solder ball.

Systems and methods for providing a ball grid array connection include providing a circuit board having a circuit board surface including a plurality of pads. A ball grid array component includes a plurality of solder balls. The ball grid array component is coupled to the circuit board to position each of the plurality of solder balls adjacent a respective one of the plurality of pads. A solder reflow process is then performed to produce a plurality of soldered connections from each of the plurality of solder balls and a respective one of the plurality of pads. At least one spacer member is provided between the ball grid array component and the circuit board during the solder reflow process to provide a mechanical stop between the ball grid array component and the circuit board and a minimum height for each of the plurality of soldered connections.

A device includes at least one integrated passive device having at least one bond pad; at least one semiconductor device having at least one bond pad; and at least one connection structure arranged on the at least one integrated passive device. Additionally, the at least one connection structure includes a solder portion configured to form a solder connection to the at least one bond pad of the at least one semiconductor device.

A semiconductor substrate is provided with an annular cavity extending from a front side of the substrate to an opposite rear side. A metallization is applied in the annular cavity, thereby forming a through-substrate via and leaving an opening of the annular cavity at the front side. A solder ball is placed above the opening and a reflow of the solder ball is effected, thereby forming a void of the through-substrate via, the void being covered by the solder ball.