One variation of a method for fabricating a garment includes: applying a first mask to a first side of a fabric substrate coated with a conductive material; applying a second maskmirrored image of the first maskto a second side of the fabric substrate opposite the first side; applying an etchant to the fabric substrate to remove conductive material outside of the first mask; arranging a conductive interface pad of a component carrier over an electrode defined by remaining conductive material on the fabric substrate, the component carrier including a flexible substrate and a rigid electrical component mounted to the flexible substrate, the conductive interface pad extending from a terminal of the rigid electrical component across a region of the flexible substrate; mechanically fastening the component carrier to the fabric substrate to form a garment insert including an electrical circuit; and incorporating the garment insert into the garment.

One variation of a method for fabricating a garment includes: applying a first mask to a first side of a fabric substrate coated with a conductive material; applying a second maskmirrored image of the first maskto a second side of the fabric substrate opposite the first side; applying an etchant to the fabric substrate to remove conductive material outside of the first mask; arranging a conductive interface pad of a component carrier over an electrode defined by remaining conductive material on the fabric substrate, the component carrier including a flexible substrate and a rigid electrical component mounted to the flexible substrate, the conductive interface pad extending from a terminal of the rigid electrical component across a region of the flexible substrate; mechanically fastening the component carrier to the fabric substrate to form a garment insert including an electrical circuit; and incorporating the garment insert into the garment.

Provided is a substrate holding unit that holds a pair of substrates that are aligned and layered, comprising a first holding member that holds one of the substrates; a plurality of members to be joined that are connected to the first holding member; a second holding member that holds the other of the substrates to face the one of the substrates; a plurality of joining members that exert an adhesion force on the members to be joined and are connected to the second holding member at positions corresponding to positions of the members to be joined; and an adhesion restricting section that restricts the adhesion force until the substrates are aligned.

Lighting modules and methods of manufacturing the same. The lighting module described herein may include a flexible printed circuit board substrate, light emitting diodes mounted on one side of the printed circuit board substrate, and thermally-conductive substrate plates opposite of the light emitting diodes to provide structural support and thermal management.

An electronic device includes a glass substrate, a first metal layer, a second metal layer, and a third metal layer. The glass substrate includes a first surface, a second surface corresponding to the first surface, and at least two first through holes. The first through hole includes a third surface, and the third surface is connected to the first surface and the second surface. A first conductive layer is disposed on the first surface. A second conductive layer is disposed on the second surface. A third conductive layer is disposed on the third surface and is electrically connected to the first conductive layer and the second conductive layer. The first through hole has a major axis and a minor axis in a top view direction. A method of manufacturing the electronic device is also included.

A dielectric layer for manufacturing a component carrier is described. The dielectric layer includes a first section including a first material having a first material property; and a second section including a second material having a second material property. The second material property is different from the first material property. A method for manufacturing such a component carrier and a component carrier including such a dielectric layer is further described.

A manufacturing method including mounting a ceramic plate on a circuit board such that the ceramic plate can be prevented from falling over. An electronic circuit module manufacturing method includes mounting a ceramic plate including a resin layer on a principal surface of a circuit board in such a manner that a principal surface of the ceramic plate is perpendicular or substantially perpendicular to the principal surface of the circuit board, and removing the resin layer from the principal surface of the ceramic plate mounted on the circuit board. In the step of mounting, the ceramic plate is supported by the resin layer and is thus prevented from falling over.

A display panel and a display are provided. The display panel includes a glass substrate, at least one driving chip and a flexible printed circuit, wherein the at least one driving chip is electrically connected to the flexible printed circuit. Both the at least one driving chip and the flexible printed circuit are arranged on the glass substrate together to reduce the thickness of the display.

A highly heat-dissipating flexible printed circuit board (GFPCB) efficiently emits heat transferred from a heat source such as an LED to the flexible printed circuit board. The highly heat-dissipating flexible printed circuit board comprises: a flexible board layer which is formed in a flexibly bendable thin-film form by bonding a polyimide (PI) film to the lower side of a copper (Cu) film using an adhesive and has a heat element installed on the upper side thereof; and a heat dissipation layer which is formed in a thin-film form by coating any one of graphitic carbon and a graphite powder binder on the upper side of an aluminum (Al) film and is bonded to the lower side of the flexible board layer using a pressure sensitive adhesive (PSA) to receive heat generated and transferred from the heat element and emit the heat to the outside.

A circuit board structure includes a first sub-circuit board, a second sub-circuit board, and a third sub-circuit board. The first sub-circuit board has an upper surface and a lower surface opposite to each other, and includes at least one first conductive through hole. The second sub-circuit board is disposed on the upper surface of the first sub-circuit board and includes at least one second conductive through hole. The third sub-circuit board is disposed on the lower surface of the first sub-circuit board and includes at least one third conductive through hole. At least two of the first conductive through hole, the second conductive through hole, and the third conductive through hole are alternately arranged in an axial direction perpendicular to an extending direction of the first sub-circuit board. The first, second and third sub-circuit boards are electrically connected to one another.