A method of manufacturing a flexible electronic circuit is provided. The method may include forming a positive photoresist mold on a flexible polymer substrate having a plurality of metal traces. The method may also include applying a conformal material coating over the positive photoresist mold, the flexible polymer substrate, and the metal traces. The method may further include removing an excess of the conformal material coating by running a blade over the positive photoresist mold. The method may also include removing the positive photoresist mold to reveal a cavity defined by the conformal material coating. The method may further include dispensing an anisotropic conductive paste into the cavity and inserting a chip into the cavity and bonding the chip to the metal traces.

An organic substrate includes a core layer including organic materials; a first buildup layer on a top surface of the core layer; a second buildup layer on a bottom surface of the core layer; and at least one correction layer formed on at least one part of surfaces of the first buildup layer and the second buildup layer, wherein the correction layer has a thickness which has been calculated using properties of constituent materials including the coefficient of thermal expansion (CTE) and the Young's modulus of the core layer, and CTEs and the Young's modulus of the first and the second buildup layers for reducing warpage of the organic substrate.

A light emitting device and a keyboard structure are provided. The light emitting device includes a circuit board and multiple light emitting units. The circuit board includes a substrate, a first conductive pad, multiple second conductive pads, and multiple third conductive pads. The first conductive pad and the second conductive pads are disposed on a first board surface of the substrate. The first conductive pad has a symmetrical shape and a symmetrical axis. The symmetrical axis passes through the second conductive pads. The third conductive pads are disposed on a second board surface of the substrate. Each of the third conductive pads is electrically coupled to the first conductive pad and the second conductive pads by multiple conductive columns. Each of the light emitting units is connected to the first conductive pad and one of the second conductive pads.

An LED module, including a carrier having high reflectivity, wherein a metal layer, preferably a silver layer or a layer of high-purity aluminum, is applied to the carrier. Also disclosed is an LED module, including a carrier having high reflectivity, wherein a metal layer is applied to the carrier, at least one LED chip, and a dam, wherein the metal layer partially covers the surface of the carrier lying under the dam.

A wiring body includes: a first insulator; a conductor disposed on a first surface of the first insulator and that includes a terminal; and a second insulator disposed on the first surface to cover the conductor. The second insulator includes: an opening from which the terminal is exposed; and an end face that delimits the opening and that includes a first face, a second face that is farther away from the first insulator than the first face, and an edge that connects the first face and the second face.

A circuit board element including an insulating layer, a circuit layer, a protective layer, a plurality of solder balls, and a dielectric layer is provided. The circuit layer is disposed on the insulating layer. The protective layer is disposed on the circuit layer and has a plurality of openings exposing the circuit layer. The plurality of solder balls are disposed on the protective layer and embedded in the corresponding openings. The dielectric layer is disposed between the solder balls and the protective layer. A manufacturing method of a circuit board element is also provided.

A cable connection structure includes: a cable having a core and a jacket made of an insulating material to cover the core; and a substrate connected with the cable. The substrate includes: a base material made of an insulating material; an external connection electrode formed on a surface of the base material and connected with the core; and a via provided in the base material and having an end exposed from a mounting surface of the substrate on which the cable is mounted, the via being connected with the external connection electrode. The via is provided at least at one of both ends of a surface of the external connection electrode perpendicular to an axial direction of the cable, on a proximal end side of the cable.

The invention relates to a method (20) for producing an electric circuit (2) in which a circuit carrier (4) comprising a first contact surface (14) and a second contact surface (16) is provided. An insulating body (26) is placed on the circuit carrier (4), wherein the insulating body (26) at least partially covers the first contact surface (14) and the second contact surface (16), and the insulating body (26) comprises a recess (34) in the region of both contact surfaces (14, 16). A flowable electro-conductive medium (44) is introduced into the insulating body (26). The invention also relates to an electric circuit (2) and to a further method (60) for producing an electric circuit (2).

It is disclosed an electrical interconnection system comprising: i) an interconnection board comprising an intrinsically non elastic substrate, said substrate having a first face and an opposed second face, and at least one conductive track on and/or within at least a portion of said substrate; ii) a stretchable interconnect comprising an intrinsically elastic substrate, said substrate comprising at least one well or groove comprising at least one compliant conductive element therein, said at least one well or groove being configured to accommodate said at least one conductive track of said interconnection board; and iii) at least one bolus of an electrically conductive paste located within said at least one well or groove, configured to electrically connect said at least one compliant conductive element with said at least one conductive track.

A method for manufacturing a printed wiring board includes forming metal posts on a conductor circuit formed on a resin insulating layer, forming the outermost resin layer on the resin insulating layer such that the metal posts is embedded in the outermost resin layer, forming a mask at a dam formation site for a dam structure of the outermost resin layer to surround at least part of a pad group including the metal posts on the outermost resin layer, and reducing a thickness of the outermost resin layer exposed from the mask such that end portions of the metal posts are exposed from the outermost resin layer, that the metal posts form the pad group, and that the outermost resin layer has the dam structure forming part of the outermost resin layer and formed to surround at least part of the pad group including the metal posts.