A manufacturing method for a printed circuit board includes: passing a first laser beam output from a laser output device through a first aperture so as to define an outer diameter of the first laser beam, positioning the first laser beam by an optical axis positioning device including a galvano device and an fθ lens, and irradiating the printed circuit board with the first laser beam such that a through-hole is formed in a copper layer; and passing a second laser beam output from the laser output device through a second aperture so as to define an outer diameter of the second laser beam whereby a diameter of the second aperture is smaller than a diameter of the first aperture, positioning the second laser beam by the optical axis positioning device, and irradiating the printed circuit board with the second laser beam such that an insulating layer is processed.

Sheet comprising a flexible support and a coating at least partially covering at least one face of the support, the support being made of a support material exhibiting dielectric properties, the coating being made of a coating material different from the support material and exhibiting magneto-dielectric properties or dielectric properties.

Systems and methods that enable printing of conformal materials and other waterproof coating materials at high resolution. An initial printing of a material on edges of a component is performed at high resolution in a first printing step, and a subsequent printing of the material on remaining surfaces of the component is applied in a second printing step, with or without curing of the material printed on the edges between the two printing steps. The printing of the material may be performed by a laser-assisted deposition or using another dispensing system to achieve a high resolution printing of the material and a high printing speed.

A wiring substrate includes a first insulating layer, a first conductor layer, a second insulating layer, a second conductor layer, a connection conductor, and a coating film. The first conductor layer includes a conductor pad and a wiring pattern such that the conductor pad is formed in contact with the connection conductor and that the wiring pattern is covered by the coating film, the conductor pad has a surface facing the second insulating layer and having first surface roughness higher than surface roughness of a surface of the wiring pattern, and the coating film has opening exposing a portion of the surface of the conductor pad from the coating film and having area larger than area of interface between the conductor pad and the connection conductor and that the connection conductor is formed on the portion of the surface of the conductor pad and is separated from the coating film.

A circuit board according to the present disclosure includes a substrate that is composed of a ceramic(s), and an electrically conductive layer that is positioned in contact with the substrate. The substrate includes a groove around the electrically conductive layer. Furthermore, an electronic device according to the present disclosure includes a circuit board with a configuration as described above, and an electronic component that is positioned on the electrically conductive layer.

A reel-to-reel method to laser-ablate a circuitry pattern on the fly in a reel-to-reel machine as part of a process to fabricate a printed flexible circuit. The laser ablation method includes using an appropriate laser to irradiate a metal sheet thus ablating the edges of an intended circuitry pattern. Slugs can be removed by using an optional sacrificial liner, and the slugs can be optionally ablated into smaller parts first. The laser ablation can also include an optional method of creating tie bars to provide structural support to the web of circuitry patterns.

A substrate includes electrically-conductive tracks. A semiconductor chip is arranged on the substrate and electrically coupled to selected ones of the electrically-conductive tracks. Containment structures are provided at selected locations on the electrically-conductive tracks, where the containment structures have respective perimeter walls defining respective cavities. Each cavity is configured to accommodate a base portion of a pin holder. These pin holders are soldered to the electrically-conductive tracks within the cavities defined by the containment structures. Each containment structure may be formed by a ring of resist material configured to receive solder and maintain the pin holders in a desired alignment position.

A method for fabrication includes providing a donor sheet, including a donor substrate, which is transparent in a specified spectral range, a sacrificial layer, which absorbs optical radiation within the specified spectral range and is disposed over the donor substrate, and a donor film, which includes a paste and is disposed over the sacrificial layer. The donor sheet is positioned so that the donor film is in proximity to a target location on an acceptor substrate. A pulsed laser beam impinges on the sacrificial layer with a pulse energy and spot size selected so as to ablate the sacrificial layer, thus causing a viscoelastic jet of the paste to be ejected from the donor film and to deposit, at the target location on the acceptor substrate, a dot having a diameter less than the spot size of the laser beam.

A method can be used for manufacturing a metal substrate structure for a semiconductor power module. A plurality of terminals are welded to a metal top layer. After the welding, a dielectric layer is coupled between the metal top layer and a metal bottom layer. The dielectric can be laminated or molded, as examples.

Methods and systems for creating a device having a switch trace are disclosed. The systems and methods described herein may include a device that has a chassis, the chassis having a top and a bottom, at least one antenna affixed to the top of the chassis, a first laser direct structuring-fabricated (LDS) trace, a second LDS trace, and a button, the button connected to the first LDS trace and the top of the chassis, wherein the button is configured to contact the second LDS trace when the button is depressed and complete a circuit between the first LDS trace and the second LDS trace upon contact.