A three-dimensional wiring board production method is provided that includes: a preparation step of preparing a resin film having a breaking elongation of 50% or more; a first metal film formation step of forming a first metal film on a surface of the resin film; a pattern formation step of performing patterning on the first metal film to form a desired pattern; a three-dimensional molding step of performing three-dimensional molding by heating and pressurizing the resin film; and a second metal film formation step of forming a second metal film on the first metal film having a pattern formed thereon. In the first metal film formation step, metal is deposited in a particle state to form the first metal film in a porous state.

In a method for producing a printed circuit board consisting of at least two printed circuit regions, wherein the printed circuit board regions each compromise at least one conductive layer and/or at least one device or once conductive component, wherein printed circuit board regions to be connected to another one, in the region of in each case at least one lateral surface directly adjoining one another, are connected to one another by a coupling or connection, and wherein, after a coupling or connection of printed circuit board regions, at least one additional layer or ply of the printed circuit board is applied over the printed circuit board regions, the additional layer is embodied as a conductive layer, which is contact-connected via plated-through holes to conductive layers or devices or components integrated in the printed circuit board regions.

A method of manufacturing an intermediate product for an interposer including a glass substrate having a plurality of through holes is provided. The method includes a step of forming a resin layer on a support substrate, and a step of forming a laminated body by adhering the glass substrate having the plurality of through holes on the resin layer. The glass substrate having the plurality of through holes has a thickness within a range of 0.05 mm to 0.3 mm.

A method for making a microelectronic unit includes forming a plurality of wire bonds on a first surface in the form of a conductive bonding surface of a structure comprising a patternable metallic element. The wire bonds are formed having bases joined to the first surface and end surfaces remote from the first surface. The wire bonds have edge surfaces extending between the bases and the end surfaces. The method also includes forming a dielectric encapsulation layer over a portion of the first surface of the conductive layer and over portions of the wire bonds such that unencapsulated portions of the wire bonds are defined by end surfaces or portions of the edge surfaces that are unconvered by the encapsulation layer. The metallic element is patterned to form first conductive elements beneath the wire bonds and insulated from one another by portions of the encapsulation layer.

The present invention consists of an implantable device with at least one package that houses electronics that sends and receives data or signals, and optionally power, from an external system through at least one coil attached to at least one package and processes the data, including recordings of neural activity, and delivers electrical pulses to neural tissue through at least one array of multiple electrodes that are attached to the at least one package. The device is adapted to electrocorticographic (ECoG) and local field potential (LFP) signals. A brain stimulator, preferably a deep brain stimulator, stimulates the brain in response to neural recordings in a closed feedback loop. The device is advantageous in providing neuromodulation therapies for neurological disorders such as chronic pain, post traumatic stress disorder (PTSD), major depression, or similar disorders. The invention and components thereof are intended to be installed in the head, or on or in the cranium or on the dura, or on or in the brain.

A wiring board includes a substrate, wiring, and a reinforcing part. The substrate is stretchable, and includes a first surface and a second surface located opposite to the first surface. The wiring is located at the first surface side of the substrate. The reinforcing part overlaps the wiring when viewed in a direction normal to the first surface of the substrate. The substrate has a control region and a non-control region. The control region overlaps the reinforcing part. The non-control region does not overlap the reinforcing part. The non-control region is positioned to sandwich the control region in a direction orthogonal to the direction in which the wiring extends.

A method of making a printed circuit board and a printed circuit board including a plurality of plastic substrate parts having one or more first substrate parts each having at least one coupling means, and one or more second substrate parts each having at least one receiving means to receive the coupling mean. At least one of the plurality of plastic substrate parts is formed with a further structural element, and at least two of the plurality of plastic substrate parts are connected to each other through the at least one coupling means and the at least one receiving means. The connected substrate parts include a circuit.

The present application discloses a light-emitting device including a first support structure having a first surface, a plurality of light-emitting elements arranged on the first surface, and a first adhesive layer arranged on the first support structure. Each light-emitting element has a side wall, a bottom surface, a first electrode pad, and a second electrode pad arranged on the bottom surface. The first adhesive layer surrounds the side wall and does not directly contact the bottom surface. The first support structure includes a plurality of through holes located on positions corresponding to the first electrode pad and the second electrode pad.

A method of manufacturing a printed circuit board or a sub-assembly thereof comprises the following steps: providing at least two elements (1, 3) of insulating material coupling or connecting the elements (1, 3) of insulating material on at least one adjacent side surface covering the elements (1, 3) of insulating material with a layer (4) of conductive material on at least one surface building up at least one further layer (5, 6, 7, 8) of the printed circuit board (10) at least partly on the elements (1, 3) of insulating material,
wherein the elements (1, 3) of insulating material are made of insulating material having different mechanical, chemical or physical properties.

Furthermore a printed circuit board (10) or sub-assembly thereof is provided.

A circuit board includes a first substrate, a second substrate, a third substrate, a plurality of conductive structures and a conductive via structure. The second substrate is disposed between the first substrate and the third substrate. The third substrate has an opening and includes a first dielectric layer, a second dielectric layer, and a third dielectric layer. The opening penetrates the first dielectric layer and the second dielectric layer, and the third dielectric layer fully fills the opening. The conductive via structure penetrates the first substrate, the second substrate, the third dielectric layer of the third substrate, and is electrically connected to the first substrate and the third substrate to define a signal path. The first substrate, the second substrate, and the third substrate are electrically connected through the conductive structures to define a ground path, and the ground path surrounds the signal path.