A method of manufacturing an ultrasound imaging device involves forming an interposer structure, including forming a first metal material within openings through a substate and on top and bottom surfaces of the substrate, patterning the first metal material, forming a dielectric layer over the patterned first metal material, forming openings within the dielectric layer to expose portions of the patterned first metal material, filling the openings with a second metal material, forming a third metal material on the top and bottom surfaces of the substrate, and patterning the third metal material. The method further involves forming a packaging structure for an ultrasound-on-chip device, including attaching a multi-layer flex substrate to a carrier wafer, bonding a first side of an ultrasound-on-chip device to the multi-layer flex substrate, bonding a second side of the ultrasound-on-chip device to a first side of the interposer structure, and removing the carrier wafer.

A method for introducing at least one cutout, in particular in the form of an aperture, into a sheetlike workpiece having a thickness of less than 3 mm, involving detecting a laser beam onto the surface of the workpiece, selecting the exposure time of the laser beam to be extremely short so that only a modification of the workpiece concentrically around a beam axis of the laser beam occurs, such a modified region having defects resulting in a chain of blisters, and, as a result of the action of a corrosive medium, anisotropically removing material by successive etching in those regions of the workpiece that are formed by the defects and have previously been modified by the laser beam, resulting, along the cylindrical zone of action, in producing a cutout as an aperture in the workpiece.

A component carrier includes an electrically insulating layer structure having a first main surface and a second main surface with a through hole extending through the electrically insulating layer structure between the first main surface and the second main surface. An electrically conductive bridge structure connects opposing sidewalls of the electrically insulating layer structure delimiting the through hole. A vertical thickness of the electrically insulating layer structure is not more than 200 μm and a narrowest vertical thickness of the bridge structure is at least 20 μm.

Disclosure provides an adapter board and a method for making the adapter board, which includes providing a mold in which a plurality of first fixing plates and second fixing plates are provided, providing a plurality of wires sequentially passed through the plurality of first fixing plates and the second fixing plate, injecting a non-conductive material into the cavity to form a body, and cutting the body along both sides of the first fixing plates and the second fixing plates to obtain a plurality of board bodies. The first fixing plates are provided with a plurality of first fixing holes, and the second fixing plates are provided with a plurality of second fixing holes. The board body includes a first surface and a second surface. A plurality of first connection pads are formed on the first surface, and a plurality of second connection pads are formed on the second surface.

A packaging substrate includes a core layer including a glass substrate with a first surface and a second surface facing each other, and a plurality of core vias. The plurality of core vias penetrating through the glass substrate in a thickness direction, each comprising a circular core via having a circular opening part and a non-circular core via having a 1.2 or more aspect ratio in the x-y direction of an opening part. One or more electric power transmitting elements are disposed on the non-circular core via.

Pastes are disclosed that are configured to coat a passage of a substrate. When the paste is sintered, the paste becomes electrically conductive so as to transmit electrical signals from a first end of the passage to a second end of the passage that is opposite the first end of the passage. The metallized paste contains a lead-free glass frit, and has a coefficient of thermal expansion sufficiently matched to the substrate so as to avoid cracking of the sintered paste, the substrate, or both, during sintering.

A method for manufacturing a ceramic electronic component includes: forming a ceramic laminate by stacking ceramic green sheets on which internal electrode patterns are formed; obtaining an image of an upper portion of the ceramic laminate; determining cutting regions based on the image; and cutting the ceramic laminate by irradiating the cutting regions with a laser.

Embodiments disclosed herein include electronic packages. In an embodiment, the electronic package comprises a core with a first surface and a second surface, where the core comprises glass. In an embodiment, a first buildup layer is over the first surface of the core, and a second buildup layer is under the second surface of the core. In an embodiment, the electronic package further comprises a via through the core between the first surface of the core and the second surface of the core, and a plane into the first surface of the core, where a width of the plane is greater than a width of the via.

A composite circuit board includes a composite circuit board unit, a first solder mask formed on a first metal protection layer of the composite circuit board unit, and a second solder mask formed on a second metal protection layer of the composite circuit board unit. Two ends of a first outer conductive circuit are bent back toward each other and spaced apart a predetermined distance to form a first window. Two ends of a second outer conductive circuit are bent back toward each other and spaced apart a predetermined distance to form a second window.

A multi-piece wiring substrate includes a matrix substrate including first and second insulating layers, and interconnection substrate regions arranged in a matrix. The matrix substrate includes dividing grooves opposing each other and disposed along boundaries between the interconnection substrate regions, and through-holes penetrating the matrix substrate in a thickness direction at positions where the dividing grooves are disposed. The inner surface conductor gradually decreases in thickness from a thick portion in a middle of the inner surface conductor, to thin portions disposed on a side of a boundary between the first and second insulating layers and on a first main surface side, and includes inclination portions each of which gradually increases in thickness from a boundary between corresponding one of the dividing grooves and the inner surface conductor to an inner surface of the inner surface conductor, in vertical sectional view.