A first conductive pad is connected to a second conductive pad by using a post-transition metal and a nanoporous metal. An example of the post-transition metal is indium. An example of the nanoporous metal is nanoporous gold. A block of the post-transition metal is formed on the first conductive pad. The block of the post-transition metal is coated with a layer of anti-corrosion material. A block of the nanoporous metal is formed on the second conductive pad. The block of the post-transition metal and the block of the nanoporous metal are thermal compressed to form an alloy between the first conductive pad and the second conductive pad.

An integrated circuit structure includes a substrate, a metal pad over the substrate, a passivation layer having a portion over the metal pad, and a polymer layer over the passivation layer. A Post-Passivation Interconnect (PPI) has a portion over the polymer layer, wherein the PPI is electrically coupled to the metal pad. The integrated circuit structure further includes a first solder region over and electrically coupled to a portion of the PPI, a second solder region neighboring the first solder region, a first coating material on a surface of the first solder region, and a second coating material on a surface of the second solder region. The first coating material and the second coating material encircle the first solder region and the second solder region, respectively. The first coating material is spaced apart from the second coating material.

A connection arrangement for forming a component carrier structure is disclosed. The connection arrangement includes a first electrically conductive connection element and a second electrically conductive connection element. The first connection element and the second connection element are configured such that, upon connecting the first connection element with the second connection element along a connection direction, a form fit is established between the first connection element and the second connection element that limits a relative motion between the first connection element and the second connection element in a plane perpendicular to the connection direction. A component carrier and a method of forming a component carrier structure are also disclosed.

The present application provides a semiconductor structure having a copper pillar within a solder bump, and a manufacturing method of the semiconductor structure. The semiconductor structure includes a substrate having a pad disposed thereon and a passivation at least partially surrounding the pad; and a conductive bump structure disposed over the passivation and the pad, wherein the conductive bump structure includes a first bump portion disposed over the passivation and the pad, a conductive pillar disposed over the first bump portion, and a second bump portion disposed over and surrounding the conductive pillar.

A package structure and a formation method of a package structure are provided. The method includes placing a semiconductor die over a redistribution structure and placing a conductive feature over the redistribution structure. The conductive feature has a support element and a solder element. The solder element extends along surfaces of the support element. The method also includes stacking an interposer substrate over the redistribution structure. The interposer substrate extends across the semiconductor die. The method further includes forming a protective layer to surround the conductive feature and the semiconductor die.

Wafer-level (chip-scale) package semiconductor devices are described that have bump assemblies configured to maintain standoff (bump) height. In an implementation, the wafer-level chip-scale package devices include an integrated circuit chip having an array of bump assemblies disposed over the integrated circuit chip. The array of bump assemblies comprises a plurality of first bump assemblies that include solder bumps composed at least substantially of a solder composition (i.e., do not include a core). The array further includes at least one second bump assembly including a solder bump having a core configured to maintain standoff height of the wafer-level package device.

Embodiments herein relate to systems, apparatuses, or processes directed to an interconnect joint that includes multiple core balls within a solder compound where the multiple core balls are substantially linearly aligned. The multiple core balls, which may include copper or be a polymer, couple with each other within the solder and form a substantially linear alignment during reflow. In embodiments, four or more core balls may be used to achieve a high aspect ratio interconnect joint with a tight pitch.

An optical module includes an optical semiconductor chip including a first electrode pad, a second electrode pad, and a third electrode pad arranged between the first electrode pad and the second electrode pad, a wiring substrate on which the optical semiconductor chip is flip-chip mounted, including a fourth electrode pad, a fifth electrode pad, and a sixth electrode pad arranged between the fourth electrode pad and the fifth electrode pad, a first conductive material connecting the first electrode pad with the fourth electrode pad, a second conductive material connecting the second electrode pad with the fifth electrode pad, a third conductive material arranged between the first conductive material and the second conductive material, connecting the third electrode pad with the sixth electrode pad, and a resin provided in an area on the second conductive material side of the third conductive material between the optical semiconductor chip and the wiring substrate.

A method of visibility event navigation includes receiving, via processing circuitry of a client device, a first visibility event packet from a server, the first visibility event packet including information representing 3D surface elements of an environmental model that are occluded from a first viewcell and not occluded from a second viewcell, the first and second viewcells representing spatial regions of a specified navigational route within a real environment modeled by the environmental model. The method also includes acquiring, surface information representing the visible surfaces of the real environment at a sensor and determining, a position in the real environment by matching the surface information to the visibility event packet information. The method further includes transmitting, the position from the client device to the server and receiving a second visibility event packet from the server if the at least one position is within the specified navigational route.

The objective of the present invention is to provide a technique that ensures conduction between a gate terminal of a semiconductor switching element and a wiring layer in a semiconductor device formed with a wiring layer inside a ceramic layer. This semiconductor device comprises: a wiring layer that is inside a ceramic layer formed above an insulation layer; and a metal layer for connecting terminals from the semiconductor switching element other than the gate terminal. The wiring layer and the gate terminal from the semiconductor switching element are connected electrically via a connection part formed from a conductive material. The connection part protrudes more than the metal layer toward the semiconductor switching element.