A stretchable wiring board that includes a stretchable substrate having a first main surface with a first region, a second region adjacent the first region, and a third region adjacent the second region; a first stretchable wiring line on the first main surface and extending over the first region; an insulating layer extending over the first region and the second region; and a second stretchable wiring line extending over the first region, the second region, and the third region. At a position in the first region where the total thickness of the first stretchable wiring line, the insulating layer, and the second stretchable wiring line is the largest, the thicknesses of the first stretchable wiring line, the insulating layer, and the second stretchable wiring line satisfy a predetermined relationship with the thickness of the second stretchable wiring line at a boundary between the second region and the third region.

A flexible circuit comprises a laminated substrate, a layer of a protective coating, and first and second components. The laminated substrate comprises a support layer and a conductive layer arranged on the support layer. The conductive layer includes conductive traces. Edges of the conductive traces taper outwardly and towards the support layer. The layer of the protective coating is deposited on the conductive traces. The first component is soldered at a first connection point on one of the conductive traces. The soldering sublimates the protective coating. The second component is connected to the conductive layer at a second connection point. The second connection point is free of the protective coating.

A circuit board being able to easily ensure flatness of solder placed on a substrate for bonding an electronic component and improve bonding reliability of the electronic component by the solder, includes: a substrate having a plurality of layers made of a conductive material; a land provided on a first layer arranged on one side of the substrate, to which the electronic component is soldered; a heat sink provided on a different layer arranged on the substrate; a via hole provided on the substrate from a part of the land over to a part of the heat sink and electrically connected to the land and the heat sink; and an insulating resist disposed on the land and surrounding the entire circumference of the via hole.

A load adaptive device includes a substrate, a first electrode, a second electrode, and a passive element. The substrate is configured with a first conductor and a second conductor, and the surface area of the first conductor and/or the surface area of the second conductor are at least 15 mm.sup.2. The distance between the center of the first conductor and the center of the second conductor is at least 9 mm. The first electrode, the second electrode and the passive element are disposed on the substrate. The first electrode is electrically connected to the first conductor. Two terminals of the passive element are electrically connected to the second conductor and the second electrode, respectively. In addition, a hand-made circuit module includes the load adaptive device and a hand-made loop. A part of the hand-made loop is consisted of a hand-bonded conductive tape.

A wiring board includes: a substrate first elastic modulus including a first surface and second surface positioned on the opposite side of the first surface; wiring positioned on the first surface side of the substrate and connected to an electrode of an electronic component mounted on the wiring board; and a reinforcing member second elastic modulus greater than the first elastic modulus and including a first reinforcing part positioned on the first surface side of the substrate or on the second surface side of the substrate and partially overlaps the electronic component mounted on the wiring board when viewed along the normal direction of the first surface of the substrate. The wiring includes a section that does not overlap the reinforcing member when viewed along the normal direction of the first surface including pluralities of peaks and valleys aligned along a planar direction of the first surface of the substrate.

A electronic device including a host connector and memory device is provided. The host connector includes a connector pin, and the memory connector includes a connection terminal electrically connected to the connector pin of the host connector. The connector pin includes a first conductor part including a conductor, a second conductor part including the conductor, the second conductor part being bent from the first conductor part in a direction towards the connection terminal, and a stub including an insulator, the stub being bent from the second conductor part in a direction away from the connection terminal. The connection terminal includes a first region including an insulator, and a second region including a conductor. The second conductor part is electrically connected to the second region, so that the host connector is electrically connected to the memory connector.

A flexible wiring substrate includes a main substrate having flexibility, a main wiring disposed over the main substrate, a second protective sheet covering the main wiring, and an insulating member partially covering the main wiring exposed from the second protective sheet and being thinner in thickness than the second protective sheet.

A method of manufacturing a flexible circuit comprises providing a laminated substrate that includes a conductive layer, an adhesive layer, and a support layer. The method comprises forming conductive traces by removing selected portions of the conductive layer and the adhesive layer by dry milling the laminated substrate. The method comprises applying a protective coating to the conductive traces. The method comprises dispensing a solder material on the protective coating at a first connection point and arranging a first component at the first connection point. The method comprises heating the solder material to remove the protective coating from the first connection point and to connect the first component to one of the conductive traces at the first connection point. The method comprises attaching a second component to the conductive layer at a second connection point that is free of the protective coating by a process other than soldering.

In order to provide a mounting structure that has high reliability and easily follows a curved surface, the mounting structure includes a flexible circuit board, a non-flexible component, and a connection portion that is provided in a region smaller than a bottom surface of the non-flexible component and connects the flexible circuit board and the non-flexible component to each other. Further, a protection resin that seals the connection portion in such a way that the flexible circuit board and the non-flexible component are separable from each other outside of the connection portion, is provided. In this configuration, the protection resin covers only a region provided with the connection portion. Thus, the connection portion is mechanically reinforced by the protection resin, and is protected from moisture and dust. Further, on an outside of the connection portion, the flexible circuit board can be bent.

A display device may include a main flexible printed circuit including a first alignment mark and electrically connected to a first panel; and a touch flexible printed circuit including a second alignment mark and electrically connected to a second panel that is perpendicular to the first panel, wherein the main flexible printed circuit is electrically connected to the touch flexible printed circuit through a pad region, and the touch flexible printed circuit includes a first overcoat region disposed between the first alignment mark and the second alignment mark.