A stretchable interconnect structure for electrically connecting electronic devices and a method of fabricating a stretchable interconnect structure for electrically connecting electronic devices. The method comprises the steps of providing an electrically conductive wire having a 3-dimensional helical form; and embedding the electrically conductive wire in a substrate made from an elastic material.

A lighting unit for a vehicle has a light source carrier with an arrangement of data lines. The lighting unit also has a plurality of light sources positioned on the light source carrier, each of which has an integrated control unit and which are interconnected via the arrangement of data lines in order to exchange data according to a predefined protocol. The rear face of the light source carrier has a plurality of cavities. The front face of the light source carrier is light-conductive, at least in the region of the cavities. The arrangement of data lines is on the rear face of the light source carrier and the line ends of the data lines lead up to or into the number of cavities. At least one light source is fitted into each of the plurality of cavities, such that each light emission surface is oriented towards the floor of the cavity and the light source is electrically contacted and held in the cavity by electrical and mechanical contact with the line ends of the data lines.

A method of printing comprises providing a component source wafer comprising components, a transfer device, and a patterned substrate. The patterned substrate comprises substrate posts that extend from a surface of the patterned substrate. Components are picked up from the component source wafer by adhering the components to the transfer device. One or more of the picked-up components are printed to the patterned substrate by disposing each of the one or more picked-up components onto one of the substrate posts, thereby providing one or more printed components in a printed structure.

A low insertion force contact includes a conductive base layer extending to a mating end including a mating interface configured for mating electrical connection to a mating contact. A silver coating layer is provided on the conductive base layer. The silver coating layer is provided at the mating end. A silver sulfide surface layer forms a solid lubricant directly on the silver coating layer. The silver sulfide surface layer forms a film defining a surface of the low insertion force contact having a controlled thickness at the mating interface.

A circuit board according to an embodiment includes an insulating layer including first to third regions; an outer circuit pattern disposed on upper surfaces of the first to third regions of the insulating layer, and a solder resist including a first part disposed on the first region of the insulating layer, a second part disposed on the second region, and a third part disposed on the third region, wherein the outer circuit pattern includes a first trace disposed on an upper surface of the first region of the insulating layer; a first pad disposed on an upper surface of the first region of the insulating layer; and a second trace disposed on an upper surface of the third region of the insulating layer; wherein an upper surface of the first part of the solder resist is positioned lower than an upper surface of the first trace; and a height of the first trace is different from a height of the first pad.

Provided are interconnects for interconnecting a set of battery cells, assemblies comprising these interconnects, methods of forming such interconnects, and methods of forming such assemblies. An interconnect includes a conductor comprising two portions electrically isolated from each other. At least one portion may include two contacts for connecting to battery cells and a fuse forming an electrical connection between these two contacts. The interconnect may also include an insulator adhered to the conductor and mechanically supporting the two portions of the conductor. The insulator may include an opening such that the fuse overlaps with this opening, and the opening does not interfere with operation of the fuse. In some embodiments, the fuse may not directly interface with any other structures. Furthermore, the interconnect may include a temporary substrate adhered to the insulator such that the insulator is disposed between the temporary substrate and the conductor.

A multilayer printed circuit board (PCB) includes a laminate between a first core and a second core. The first core is located in a middle position of the multi-layer PCB and includes a resistive heating element directly upon a first core substrate. A portion of the resistive heating element protrudes from the multi-layer PCB perimeter. A laminator that fabricates the PCB includes a platen, a power supply, a processor, and memory that has program instructions embodied therewith which are readable by the processor to cause the laminator to position the platen against a surface of the multi-layer PCB and cure the laminate by heating the multi-layer PCB with the platen and cure the laminate by heating the multi-layer PCB with the resistive heating element.

An FPC connection structure including: several strands of FPC conductor patterns coated with an insulating film; and FPC terminals each extending from one end portion of each of the FPC conductor patterns and provided in a flat type to enable spot welding on a substrate terminal unit provided on the printed circuit board.

Provided are interconnects for interconnecting a set of battery cells, assemblies comprising these interconnects, methods of forming such interconnects, and methods of forming such assemblies. An interconnect includes a conductor comprising two portions electrically isolated from each other. At least one portion may include two contacts for connecting to battery cells and a fuse forming an electrical connection between these two contacts. The interconnect may also include an insulator adhered to the conductor and mechanically supporting the two portions of the conductor. The insulator may include an opening such that the fuse overlaps with this opening, and the opening does not interfere with operation of the fuse. In some embodiments, the fuse may not directly interface with any other structures. Furthermore, the interconnect may include a temporary substrate adhered to the insulator such that the insulator is disposed between the temporary substrate and the conductor.

A low insertion force contact includes a conductive base layer extending to a mating end including a mating interface configured for mating electrical connection to a mating contact. A silver coating layer is provided on the conductive base layer. The silver coating layer is provided at the mating end. A silver sulfide surface layer forms a solid lubricant directly on the silver coating layer. The silver sulfide surface layer forms a film defining a surface of the low insertion force contact having a controlled thickness at the mating interface.