A component includes a plurality of electrical connections on a process side opposed to a back side of the component. Each electrical connection includes an electrically conductive multi-layer connection post protruding from the process side. A printed structure includes a destination substrate and one or more components. The destination substrate has two or more electrical contacts and each connection post is in contact with, extends into, or extends through an electrical contact of the destination substrate to electrically connect the electrical contacts to the connection posts. The connection posts or electrical contacts are deformed. Two or more connection posts can be electrically connected to a common electrical contact.

The invention provides a light generating device (1000) comprising (a) a first interconnect (110), (b) a second interconnect (120), (c) a solid state light source (130), and (d) a multilayer stack (200) comprising a first multilayer (210) and a second multilayer (220), wherein: each multilayer (210,220) of the multilayer stack (200) comprises (i) a flexible support layer (250), and (ii) a conductive layer (230); the first interconnect (110) connects the solid state light source (130) and the conductive layer (230) of the first multilayer (210); the first multilayer (210) comprises an opening (215), wherein at least part of the second interconnect (120) is arranged in the opening (215); the second interconnect (120) connects the solid state light source (130) and the conductive layer (230) of the second multilayer (220); and the first interconnect (110), the second interconnect (120), and the conductive layers (230) are each individually one or more of thermally conductive and electrically conductive.

An item may include fabric having insulating and conductive yarns or other strands of material. The conductive strands may form signal paths. Electrical components can be mounted to the fabric. Each electrical component may have an electrical device such as a semiconductor die that is mounted on an interposer substrate. The interposer may have contacts that are soldered to the conductive strands. A protective cover may encapsulate portions of the electrical component. To create a robust connection between the electrical component and the fabric, the conductive strands may be threaded through recesses in the electrical component. The recesses may be formed in the interposer or may be formed in a protective cover on the interposer. Conductive material in the recess may be used to electrically and/or mechanically connect the conductive strand to a bond pad in the recess. Thermoplastic material may be used to seal the solder joint.

An item may include fabric having insulating and conductive yarns or other strands of material. The conductive strands may form signal paths. Electrical components can be mounted to the fabric. Each electrical component may have an electrical device such as a semiconductor die that is mounted on an interposer substrate. The interposer may have contacts that are soldered to the conductive strands. A protective cover may encapsulate portions of the electrical component. To create a robust connection between the electrical component and the fabric, the conductive strands may be threaded through recesses in the electrical component. The recesses may be formed in the interposer or may be formed in a protective cover on the interposer. Conductive material in the recess may be used to electrically and/or mechanically connect the conductive strand to a bond pad in the recess. Thermoplastic material may be used to seal the solder joint.

Examples of semiconductor packages with stacked RDLs described herein may include, for example, a first RDL comprising multiple RDL layers coupled to a second RDL comprising multiple RDL layers using copper pillars and an underfill in place of a conventional substrate. The examples herein may use RDLs instead of substrates to achieve smaller design feature size (x, y dimensions reduction), thinner copper layers and less metal usage (z dimension reduction), flexibility to attach semiconductor dies and surface mount devices (SMD) on either side of the package, and less number of built-up RDL layers.

The disclosure relates to systems and methods for using additive manufacturing techniques for fabricating ball grid array (BGA) surface mounting pads (SMP), and surface mounted technology devices (SMT) package sockets. More specifically, the disclosure relates to additive manufacturing methods for additively manufactured electronic (AME) circuits such as a printed circuit board (PCB), and/or flexible printed circuit (FPC), and/or high-density interconnect printed circuit board (HDIPCB) each having integrated raised and/or sunk BGA SMP, and or surface mounting sockets for SMT device(s) defined therein, and methods of coupling surface mounted devices such as BGA and/or SMT thereto.

A component includes a plurality of electrical connections on a process side opposed to a back side of the component. Each electrical connection includes an electrically conductive multi-layer connection post protruding from the process side. A printed structure includes a destination substrate and one or more components. The destination substrate has two or more electrical contacts and each connection post is in contact with, extends into, or extends through an electrical contact of the destination substrate to electrically connect the electrical contacts to the connection posts. The connection posts or electrical contacts are deformed. Two or more connection posts can be electrically connected to a common electrical contact.

The disclosure relates to systems and methods for using additive manufacturing techniques for fabricating ball grid array (BGA) surface mounting pads (SMP), and surface mounted technology devices (SMT) package sockets. More specifically, the disclosure relates to additive manufacturing methods for additively manufactured electronic (AME) circuits such as a printed circuit board (PCB), and/or flexible printed circuit (FPC), and/or high-density interconnect printed circuit board (HDIPCB) each having integrated raised and/or sunk BGA SMP, and or surface mounting sockets for SMT device(s) defined therein, and methods of coupling surface mounted devices such as BGA and/or SMT thereto.

According to various examples, a device is described. The device may include a printed circuit board. The device may also include a first recess in the printed circuit board, wherein the first recess comprises a circular side surface and a bottom surface. The device may also include a first solder ball disposed in the first recess. The device may also include a first conductive wall positioned behind the circular side surface of the first recess, wherein the first conductive wall surrounds a side surface of the first solder ball.

Systems and methods for simultaneously coupling a plurality of high speed electrical connectors to a Printed Wiring Board (“PWB”). The methods comprise: obtaining a composite electrical connector comprising the plurality of high speed electrical connectors which are serially arranged in a side-by-side manner and coupled to each other; automatedly engaging a smooth surface of the composite electrical connector; placing the composite electrical connector on the PWB so that pins of the plurality of high speed electrical connectors are concurrently inserted into vias formed in the PWB; and coupling the composite electrical connector to the PWB by soldering the pins in the vias.