Particular embodiments described herein provide for an electronic device can include a support structure, a radiation source on the support structure, and a radiation shield around the radiation source. The radiation shield includes a wall secured to the support structure, a vacuum bag on the wall, where the vacuum bag has an inside air pressure less than an air pressure outside the vacuum bag, and a lid. The air pressure inside the vacuum bag is less than the atmospheric pressure outside the vacuum bag. When the vacuum is created in the vacuum bag, the vacuum bag deforms and compresses to help provide a vacuum-based mechanical loading that helps to create an applied load on the one or more radiation sources by the lid.

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.

An electronic element mounting substrate includes a first substrate that has a first main surface, has a rectangular shape, and has a mounting portion for an electronic element on the first main surface, and a second substrate that is located on a second main surface opposite to the first main surface, is made of a carbon material, has a rectangular shape, has a third main surface facing the second main surface and a fourth main surface opposite to the third main surface, in which the third main surface or the fourth main surface has heat conduction in a longitudinal direction greater than heat conduction in a direction perpendicular to the longitudinal direction, and that has a recessed portion on the fourth main surface.

A component carrier includes a stack with at least one electrically conductive layer structure and at least one electrically insulating layer structure. At least one electrically insulating layer structure has at least partly tapering through holes filled substantially completely with an electrically conductive filling. The at least one electrically conductive layer structure and the electrically conductive filling are made of the same material. In addition, different ones of the through holes of one electrically insulating layer structure are tapering in opposite directions.

Provide are a method for manufacturing a wiring board or a wiring board material, and the wiring board obtained by the method, which allows columnar metal members to be inserted into the wiring board at once using a simple operation, enables alignment without requiring strict accuracy, can handle columnar metal members having different shapes, and imparts sufficiently high adhesive strength to the columnar metal members. The method includes the steps of: laminating a laminate material LM including the support sheet 10 having the columnar metal members 14 formed thereon, a wiring board WB or a wiring board material WB′ having a plurality of openings in portions corresponding to the columnar metal members 14, and a prepreg 16′ having a plurality of openings in portions corresponding to the columnar metal members 14 and containing a thermosetting resin such that the columnar metal members 14 are positioned in the respective openings; integrating the laminate material LM by heating and pressing to obtain a laminate LB including a thermosetting resin filled between an inner surface of each of the openings of the wiring board WB or the wiring board material WB′ and each of the columnar metal members 14; and peeling at least the support sheet 14 from the laminate LB.

In an insulating circuit substrate, aluminum sheets formed of aluminum or an aluminum alloy are laminated and bonded to a surface of a ceramic substrate and, in the aluminum sheets, Cu is solid-solubilized at a bonding interface with the ceramic substrate and a ratio B/A between a Cu concentration A mass % at the bonding interface and a Cu concentration B mass % at a position of 100 μm in a thickness direction from the bonding interface to the aluminum sheets side is 0.30 or more and 0.85 or less.

Disclosed are aspects of apparatuses and methods of fitting a cooling device to a circuit board for cooling a high-power electronic component mounted on the circuit board. Cooling apparatuses, and arrangement thereof, are also described. The method provides the cooling device with a cooling surface having a cooling area for thermally connecting to a to-be-cooled surface of the electronic component. Fixing elements are provided for moving the cooling surface towards the circuit board. A distance position “d” of the to-be-cooled surface from the circuit board is determined, and on this basis spacer elements are selected to be interposed between the cooling device and the circuit board to limit the movement by the fixing elements to a position where the cooling area is in proximity to the to-be-cooled surface.

A circuit board according to an embodiment includes an insulating portion; and a pattern portion disposed on the insulating portion, wherein the insulating portion includes: a first insulating region, and a second insulating region disposed outside the first insulating region and spaced apart from the first insulating region with a separation region therebetween; wherein the pattern portion includes: a first pattern portion for signal transmission; and a second pattern portion including a dummy pattern separated from the first pattern portion, wherein the first pattern portion includes: a first terminal portion disposed on the first insulating region; a second terminal portion disposed on the second insulating region; and a connection portion disposed on the separation region and connecting between the first terminal portion and the second terminal portion, wherein the second pattern portion includes: a second-first pattern portion disposed on the first insulating region; and a second-second pattern portion disposed on the second insulating region and separated from the second-first pattern portion.

A method for manufacturing a PCB with an embedded thermal conductor and a PCB are provided. A sheet of copper-clad ceramic serves as a thermal conductor. A sheet of copper foil having no opening serves as an outer layer of a laminate. A part of the sheet of copper foil covering the thermal conductor is removed after a lamination process, to expose a conductive layer as the outer layer of the thermal conductor. Finally, the outer layer pattern is formed. The sheet of copper foil has no opening before the lamination process, so that the sheet of copper foil has good flatness during the lamination process, thereby avoiding wrinkles. Moreover, the sheet of copper-clad ceramic serves as the thermal conductor, so that a pattern is manufactured on the outer layer of the thermal conductor based on the exposed conductive layer.

According to one embodiment, in a memory card, a sealing portion houses the memory chip and the controller chip and includes a first main surface and a second main surface arranged on an opposite side of the first main surface. A first terminal group includes a plurality of electrode terminals arranged in a first direction inside the first main surface. A second terminal group includes a plurality of electrode terminals arranged in the first direction inside the first main surface. A conductive pattern is arranged between the first terminal group and the second terminal group in the first main surface. A conductive pattern has a longer dimension than that of the electrode terminal in the first terminal group. The conductive pattern has a longer dimension than that of the electrode terminal in the second terminal group. The conductive pattern is in a planar shape.