A method of manufacturing a wiring board includes a stacking process in which N (N is an integer equal to or greater than 2) wiring layers, end portions of which include linear conductor patterns, are stacked, with the end portions superimposed, via substrates (insulating layers) provided among the wiring layers and a laminated plate is manufactured and a removing process in which the insulating layers around the end portions of the conductor patterns of the laminated plate are removed to machine the end portions into N flying leads projecting from an end face.

Provided is an electronic component including a pad region including a plurality of pads extending along corresponding extension lines and arranged in a first direction, and a signal wire configured to receive a driving signal from the pad region, wherein the plurality of pads include a plurality of first pads arranged continuously and a plurality of second pads arranged continuously, and extension lines of the plurality of first pads substantially converge into a first point and extension lines of the plurality of second pads substantially converge into a second point different from the first point.

A display device includes a substrate, conductive pads arranged on the substrate over a plurality of rows, and a drive circuit chip including bumps arranged over a plurality of rows to be electrically connected with the conductive pads, and the conductive pads arranged in a same row are arranged in parallel, and the bumps arranged in a same row are arranged in a zigzag form so as to be partially shifted.

Flexible interconnects, flexible integrated circuit systems and devices, and methods of making and using flexible integrated circuitry are presented herein. A flexible integrated circuit system is disclosed which includes first and second discrete devices that are electrically connected by a discrete flexible interconnect. The first discrete devices includes a first flexible multi-layer integrated circuit (IC) package with a first electrical connection pad on an outer surface thereof. The second discrete device includes a second flexible multi-layer integrated circuit (IC) package with a second electrical connection pad on an outer surface thereof. The discrete flexible interconnect is attached to and electrically connects the first electrical connection pad of the first discrete device to the second electrical connection pad of the second discrete device.

A switching device has a substrate, a power semiconductor component arranged thereon, a connection device and a pressure device. The substrate has conductor tracks electrically insulated from each another. A power semiconductor component is arranged on one of the conductor tracks. The connection device is embodied as a film composite having an electrically conductive film and an electrically insulating film and forming a first and a second main surface. The switching device is connected in a circuit-conforming manner by the connection device, and a contact area of the first main surface of the power semiconductor component is connected to a first contact area of an assigned conductor track of the substrate in a force-locking and electrically conductive manner.

A submodule and an assembly include a switching device having a substrate, and printed conductors arranged thereupon. The submodule incorporates a first and a second DC voltage printed conductor, to which a first and a second DC voltage terminal element are connected in an electrically conductive manner, and an AC voltage printed conductor, to which an AC voltage terminal element is connected in an electrically conductive manner. The submodule further comprises an insulating moulding, which encloses the switching device in a frame-type arrangement. The first DC voltage terminal element, by means of a first contact section, engages with a first supporting body of the insulating moulding, and the AC voltage terminal element, by means of a second contact section, engages with a second supporting body of the insulating moulding. To this end, a first clamping device is configured to project through a first recess in the first supporting body, in an electrically insulating manner, and to form an electrically-conductive clamping connection between the first DC voltage terminal element and an associated first DC voltage connecting element, and a second clamping device is configured to project through a second recess in the second supporting body, in an electrically insulating manner, and to form an electrically-conductive clamping connection between the AC voltage terminal element and an associated AC voltage connecting element.

A method produces a plurality of optoelectronic modules, and includes: A) providing a metallic carrier assembly with a plurality of carrier units; B) applying a logic chip, each having at least one integrated circuit, to the carrier units; C) applying emitter regions that generate radiation, which can be individually electrically controlled; D) covering the emitter regions and the logic chips with a protective material; E) overmolding the emitter regions and the logic chips so that a cast body is formed, which joins the carrier units, the logic chips and the emitter regions to one another; F) removing the protective material and applying electrical conductor paths to the upper sides of the logic chips and to a cast body upper side; and G) dividing the carrier assembly into the modules.

A power electronics method and assembly produced by the method. The assembly has a substrate, having a power semiconductor element, and an adhesion layer disposed therebetween, wherein the substrate has a first surface that faces a power semiconductor element, a power semiconductor element has a third surface that faces the substrate, the adhesion layer has a second surface which, preferably across the full area, contacts the third surface and has a first consistent surface contour having a first roughness, and wherein a fourth surface of the power semiconductor element that is opposite the third surface has a second surface contour having a second roughness, said second surface contour following the first surface contour.

A submodule and an assembly include a switching device having a substrate, and printed conductors arranged thereupon. The submodule incorporates a first and a second DC voltage printed conductor, to which a first and a second DC voltage terminal element are connected in an electrically conductive manner, and an AC voltage printed conductor, to which an AC voltage terminal element is connected in an electrically conductive manner. The submodule further comprises an insulating moulding, which encloses the switching device in a frame-type arrangement. The first DC voltage terminal element, by means of a first contact section, engages with a first supporting body of the insulating moulding, and the AC voltage terminal element, by means of a second contact section, engages with a second supporting body of the insulating moulding. To this end, a first clamping device is configured to project through a first recess in the first supporting body, in an electrically insulating manner, and to form an electrically-conductive clamping connection between the first DC voltage terminal element and an associated first DC voltage connecting element, and a second clamping device is configured to project through a second recess in the second supporting body, in an electrically insulating manner, and to form an electrically-conductive clamping connection between the AC voltage terminal element and an associated AC voltage connecting element.

A method for remapping an extracted die is provided. The method includes one or more of removing an extracted die from a previous integrated circuit package, the extracted die including a plurality of original bond pads having locations that do not correspond to desired pin assignments of a new package base and bonding an interposer to the extracted die. The interposer includes first bond pads configured to receive new bond wires from the plurality of original bond pads and second bond pads corresponding to desired pin assignments of the new package base, each individually electrically coupled to one of the first bond pads and configured to receive new bond wires from package leads or downbonds of the new package base.