A mechanical subtractive method of manufacturing a flexible circuitry layer may include mechanically removing at least a portion of a conductive mesh, wherein, following the mechanical removal, a remaining portion of the conductive mesh forms at least a portion of a circuitry trace comprising an electrode; forming an electrical connection between the electrode and a terminal of an interfacing component, wherein the interfacing component comprises a connector; and encasing at least a portion of the circuit trace with an insulative layer.

Embodiments of the invention include flexible circuit board interconnections and methods regarding the same. In an embodiment, the invention includes a method of connecting a plurality of flexible circuit boards together comprising the steps applying a solder composition between an upper surface of a first flexible circuit board and a lower surface of a second flexible circuit board; holding the upper surface of the first flexible circuit board and the lower surface of the second flexible circuit board together; and reflowing the solder composition with a heat source to bond the first flexible circuit board and the second flexible circuit board together to form a flexible circuit board strip having a length longer than either of the first flexible circuit board or second flexible circuit board separately. In an embodiment the invention includes a circuit board clamp for holding flexible circuit boards together, the clamp including a u-shaped fastener; a spring tension arm connected to the u-shaped fastener; and an attachment mechanism connected to the spring tension arm. Other embodiments are also included herein.

Various methods and systems are provided for forming a flexible circuit. In one example, a method includes forming a flexible circuit comprising a plurality of contact pads arranged into a plurality of rows, each contact pad of a given row electrically coupled to one another via electrical traces and each contact pad including a via, electroplating the flexible circuit, including electroplating each via, with at least a first material, and upon confirming connectivity of each via, cutting at least some of the electrical traces at least partially.

In one example, a process for making a micro device assembly includes placing a micro device on a front part of a printed circuit board, molding a molding on the printed circuit board surrounding the micro device, and then forming a channel to the micro device in a back part of the printed circuit board.

The invention provides a light-emitting image sensing module and a method for fabricating the same. The light-emitting image sensing module includes a circuit board, an image sensor, conductive carriers, light sources, an opaque lens barrel, and a lens module. The image sensor and the conductive carriers are arranged on the circuit board. The light sources are arranged on the conductive carrier. The opaque lens barrel is penetrated by a first hole and a second hole and arranged on the circuit board. The first hole sleeves the image sensor, and the second hole sleeves the conductive carriers and the light sources. The lens module is fixed in the first hole and arranged above the image sensor. The invention uses the circuit board to carry out the packaging process of the image sensor and the light source, so as to achieve the economic benefit.

A flexible flat cable according to various embodiments of the disclosure may include a first insulation layer having a plate shape, a first conductive pattern disposed on the first insulation layer, a second conductive pattern disposed on the first insulation layer to be spaced apart from the first conductive pattern at a predetermined interval, a second insulation layer covering at least a portion of the first conductive pattern and disposed on the first insulation layer to cover the first conductive pattern, a first shield member including a first shield layer disposed on the first insulation layer and the second insulation layer to cover the first conductive pattern and the second conductive pattern, and a second shield layer disposed on the first shield layer to cover the first shield layer, and a third insulation layer surrounding the first shield layer such that at least a portion of the first shield layer of the first shield member, which is exposed between the first insulation layer and the second shield layer of the first shield member is covered.

An electronic device is provided. The electronic device includes a display substrate and a connector connected to one side of the display substrate and having a dummy pattern. A cutting part is formed in the display substrate and the connector, and the cutting part is formed adjacent to the dummy pattern.

Examples are disclosed that relate to electronically functional yarns. One example provides an electronically functional yarn comprising a core, a sheath at least partially surrounding the core, and an electronic circuit formed on the core. The circuit includes three or more control lines and more than three diode-containing circuit elements controllable by the three or more control lines, each circuit element being controllable via a corresponding set of two of the three or more control lines.

Provided are electrical harness assemblies and methods of forming such harness assemblies. A harness assembly comprises a conductor trace, comprising a conductor lead with a width-to-thickness ratio of at least 2. This ratio provides for a lower thickness profile and enhances heat transfer from the harness to the environment. In some examples, a conductor trace may be formed from a thin sheet of metal. The same sheet may be used to form other components of the harness. The conductor trace also comprises a connecting end, monolithic with the conductor lead. The width-to-thickness ratio of the connecting end may be less than that of the conductor trace, allowing for the connecting end to be directly mechanically and electrically connected to a connector of the harness assembly. The connecting end may be folded, shaped, slit-rearranged, and the like to reduce its width-to-thickness ratio, which may be close to 1.

A method of masking a feature of a substrate using a fixture includes removably coupling a fixture to a first side of the feature of the substrate, the fixture including walls configured to abut sides of the feature and extend beyond a top surface of the feature when the fixture is removably coupled to the first side. The method further includes applying a masking material to the top surface of the feature. The method further includes removably coupling the fixture to a second side of the feature, the second side opposing the first side, the walls of the fixture configured to abut the sides of the feature and extend beyond a bottom surface of the feature when the fixture is removably coupled to the second side. The method further includes applying the masking material to the bottom surface of the feature while the fixture is removably coupled.