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.

A silicon circuit board substrate is utilized in an electronic device in place of conventional PCB motherboard. The silicon circuit board substrate is adhered to the back side of a display assembly to provide structural support for the substrate. The silicon circuit board substrate and the display assembly may be electrically connected via contact pads provided on the respective sides of the substrate and the display assembly that are connected together.

The present disclosure relates to a laminated-type chip component, and more particularly, to a laminated-type chip component which can be more stably bonded by forming a groove filled with solder in a region in which an external electrode terminal of the laminated-type chip is soldered and thereby increasing the area of soldering.

An electronic module is disclosed, wherein the electronic module comprises: a first circuit board, comprising a top surface, a bottom surface, and a lateral surface connecting the top surface and the bottom surface of the first circuit board; wherein an electrode structure is disposed on the first circuit board, wherein a second circuit board is disposed under the bottom surface of the first circuit board, wherein a soldering material is disposed between the bottom surface of the electrode structure and the second circuit board and extended onto a wettable flank of the electrode structure to form a soldering structure, wherein said soldering structure comprises an outer surface that is located above the bottom surface of the first circuit board and outside the outmost portion of the lateral surface of the first circuit board.

A touch display device includes a printed circuit board and a cover. The printed circuit board has a top surface, a bottom surface and soldering points. The printed circuit board includes a first printed circuit, a light element and a second printed circuit. A part of the first printed circuit is on the top surface or the bottom surface and connected with the corresponding soldering point. The light emitting element is on the top surface and electrically connected to the first printed circuit. On the top surface, the second printed circuit does not overlap with the first printed circuit. The cover covers the printed circuit board. The cover has light transmission areas which are aligned with the light elements. The second printed circuit is configured to provide a capacitance value coupled to a capacitive sensing element coupled between the second printed circuit and the cover.

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.

A board element for board-to-board interconnect formation is provided. An embodiment includes embedding a signal via element in the board element and cutting through respective sections of the board element and the signal via element to expose a new board element edge and an outwardly facing surface of the signal via element.

A semiconductor device mounting board includes a first substrate, a second substrate, a single line, a groove, a feedthrough conductor, and a side conductor. The first substrate includes a mount area and a peripheral area. The second substrate is located in the peripheral area to align with an outer edge of the first substrate and surrounds the mount area. The signal line extends on an upper surface of the second substrate from an inner edge to an outer edge of the second substrate. The groove extends on a side surface of the first substrate from a lower surface to an upper surface of the first substrate. The feedthrough conductor is inside the second substrate and connected to the signal line. The side conductor is on an inner surface of the groove and electrically connected to the feedthrough conductor. The groove is inward from the outer edge of the second substrate.

An example sensor interposer employing castellated through-vias formed in a PCB includes a planar substrate defining a plurality of castellated through-vias; a first electrical contact formed on the planar substrate and electrically coupled to a first castellated through-via; a second electrical contact formed on the planar substrate and electrically coupled to a second castellated through-via, the second castellated through-via electrically isolated from the first castellated through-via; and a guard trace formed on the planar substrate, the guard trace having a first portion formed on a first surface of the planar substrate and electrically coupling a third castellated through-via to a fourth castellated through-via, the guard trace having a second portion formed on a second surface of the planar substrate and electrically coupling the third castellated through-via to the fourth castellated through-via, the guard trace formed between the first and second electrical contacts to provide electrical isolation between the first and second electrical contacts.

A printed circuit board includes a first transmission line provided on an insulating base, a first ground conductor, a notch portion that exposes a part of the first ground conductor, a conductor provided in the notch portion and electrically connected to the first ground conductor, and a first electrode exposed on a main surface of the insulating base facing a flexible board and electrically connected to the first transmission line. The flexible board includes a second transmission line provided on an insulating sheet, a second ground conductor, a second electrode exposed on a main surface of the insulating sheet facing the printed circuit board and connected to the second transmission line, and a third electrode exposed on the main surface of the insulating sheet and connected to the second ground conductor. The conductor and the third electrode are connected by solder.