A single-layer redistribution plate functioning as a space translator between a device under testing (“DUT”) and a testing PCB may comprise a hard ceramic plate. A DUT side of the plate may have pads configured to interface with a device under testing. Both sides of the plate may comprise traces, vias, and pads to fan out the DUT pad pattern so that the plate side opposite the DUT side has spatially translated pads configured to interface with the pads on a testing PCB. Fabricating a redistribution plate may comprise calibrating and aligning, laser milling vias, laser milling trenches and pads, copper plating, grinding and polishing, removing residual copper, and coating the copper surfaces.

A single-layer redistribution plate functioning as a space translator between a device under testing (“DUT”) and a testing PCB may comprise a hard ceramic plate. A DUT side of the plate may have pads configured to interface with a device under testing. Both sides of the plate may comprise traces, vias, and pads to fan out the DUT pad pattern so that the plate side opposite the DUT side has spatially translated pads configured to interface with the pads on a testing PCB. Fabricating a redistribution plate may comprise calibrating and aligning, laser milling vias, laser milling trenches and pads, copper plating, grinding and polishing, removing residual copper, and coating the copper surfaces.

A substrate is manufactured by drilling a chip containing groove in a composite inner layer circuit structure, having a component connecting end of a circuit layer protruding from a mounting side wall in the chip containing groove, mounting a chip component in the chip containing groove, and connecting the surface bonding pad to the component connecting end. The chip component in the present invention penetrates at least two circuit layers, and the surface bonding pad is bonded to the component connecting end of the circuit layer directly, reducing the occupied area of the chip component in each one of the circuit layers, and increasing the area for circuit disposing and the possible amount of chip components that may be mounted in the substrate.

A circuit board includes an interconnect and an insulating layer that covers the interconnect. The interconnect includes a first interconnect that is formed to serve as a recognition mark of which planar shape is a predetermined shape. The insulating layer has a through-hole of which planar shape is variant and that penetrates the insulating layer in a thickness direction of the insulating layer such that an entire upper surface of the first interconnect is exposed. The through-hole includes a first through-hole of which planar shape is a predetermined shape and that penetrates the insulating layer in the thickness direction such that the entire upper surface of the first interconnect is exposed and a second through-hole that serves as part of an inner wall surface of the first through-hole and that penetrates the insulating layer in the thickness direction.

A circuit board includes an interconnect and an insulating layer that covers the interconnect. The interconnect includes a first interconnect that is formed to serve as a recognition mark of which planar shape is a predetermined shape. The insulating layer has a through-hole of which planar shape is variant and that penetrates the insulating layer in a thickness direction of the insulating layer such that an entire upper surface of the first interconnect is exposed. The through-hole includes a first through-hole of which planar shape is a predetermined shape and that penetrates the insulating layer in the thickness direction such that the entire upper surface of the first interconnect is exposed and a second through-hole that serves as part of an inner wall surface of the first through-hole and that penetrates the insulating layer in the thickness direction.

An electronics package is disclosed. The electronics package includes a first radio frequency (RF) substrate layer, a second RF substrate layer, and a plurality of conductive layers disposed adjacent to at least one of the first RF substrate layer and the second RF substrate layer and including an inner conductive layer disposed between and adjacent to both the first RF substrate layer and the second RF substrate layer. The inner conductive layer bonds the first RF substrate layer to the second RF substrate layer. The electronics package also includes a plurality of conductive interconnects extending through the first RF substrate layer and the second RF substrate layer and electrically coupled between at least two of the plurality of conductive layers.

A printed circuit board includes a plurality of layers including attachment layers and routing layers; and columns of via patterns formed in the plurality of layers, wherein via patterns in adjacent columns are offset in a direction of the columns, each of the via patterns comprising: first and second signal vias forming a differential signal pair, the first and second signal vias extending through at least the attachment layers; and at least one conductive shadow via located between the first and second signal vias of the differential pair. In some embodiments, at least one conductive shadow via is electrically connected to a conductive surface film.

An electronics module (100), especially a power electronics module, comprising a metal-ceramic substrate (1) serving as a carrier and having a ceramic element (10) and a primary component metallization (21), an insulation layer (40) directly or indirectly connected to the primary component metallization (21), and a secondary component metallization (22) which is connected to the side of the insulation layer (40) facing away from the metal-ceramic substrate (1) and is especially isolated from the primary component metallization (21) using the insulation layer (40), wherein the ceramic element (10) has a first size (L1, D1) and the insulation layer (40) has a second size (L2, D2) and a ratio of the second size (L2, D2) to the first size (L1, D1) has a value smaller than 0.8, to form an island-like insulation layer (40) on the primary component metallization (21).

A multilayer circuit board includes an upper surface and an opposing lower surface. An electrically insulating layer is disposed between the upper and lower surfaces. A plurality of electrically conductive upper and lower rear pads are disposed proximate a rear edge on the respective upper and lower surfaces for termination of a plurality of wires. The upper and lower rear pads include respective upper and lower rear ground pads substantially aligned with each other and configured for termination of ground wires. A plurality of electrically conductive front pads are disposed proximate a front edge for insertion into a connector and electrically connected to the upper and lower rear pads. An electrically conductive via extends from the upper rear ground pad to the lower rear ground pad and makes electrical and physical contact with each of the upper and lower rear ground pads.

Embodiments described herein may be related to apparatuses, processes, and techniques directed to bridges having a glass core, where the bridges may include one or more thick traces and one or more thin traces, where the thin traces are layered closer to a surface of the glass core, and the thick traces are layered further away from the glass core. During operation, the thin traces may be used to transmit signals between the coupled dies, and the thick traces may be used to transmit power between the coupled dies. During manufacture, the rigidity and highly planner surface of the glass core may enable thinner traces closer to the surface of the glass core to be placed with greater precision resulting in increased overall quality and robustness of transmitted signals. Other embodiments may be described and/or claimed.