Some features pertain to a substrate that includes a first portion of the substrate including a first plurality of metal layers, a second portion of the substrate including a second plurality of metal layers, and a plurality of insulating layers configured to separate the first plurality of metal layers and the second plurality of metal layers. A first plurality of posts and a plurality of interconnects are coupled together such that the first plurality of posts and the plurality of interconnects couple the first portion of the substrate to the second portion of the substrate.

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.

This application relates to the field of power supply packaging technologies, and in particular, to a PCB-pinout based packaged module, including a packaged module and a pin exposed outside the packaged module. The packaged module includes a PCB and a power component. The PCB has a first surface and a second surface that are disposed opposite to each other, and the power component is disposed on the first surface or the second surface of the PCB. The power component performs communication connection with a pin located on one side of the first surface or one side of the second surface of the PCB through surface-layer copper of the PCB. The pin located on one side of the first surface or one side of the second surface of the PCB is a surface-layer copper etching pattern that is located on the PCB and that is exposed outside the packaged module.

Provided are an electronic component manufacturing method by which even a platable layer made of a difficult-to-plate material can be easily plated with good adhesion without using a special chemical solution or a photolithography technique, and an electronic component which has a peel strength of 0.1 N/mm or greater as measured by a copper foil peel test. A picosecond laser beam having a pulse duration on the order of a picosecond or a femtosecond laser beam having a pulse duration on the order of a femtosecond is emitted at a surface of a platable layer (2) in order to roughen the surface, a wiring pattern is formed using a mask (13), and a plated part (12) is formed on the surface of the wiring pattern.

A component carrier for carrying electronic components, wherein the component carrier comprises an at least partially electrically insulating core, at least one electronic component embedded in the core, and a coupling structure with at least one electrically conductive through-connection extending at least partially therethrough and having a component contacting end and a wiring contacting end, wherein the at least one electronic component is electrically contacted directly to the component contacting end, wherein at least an exterior surface portion of the coupling structure has homogeneous ablation properties and is patterned so as to have surface recesses filled with an electrically conductive wiring structure, and wherein the wiring contacting end is electrically contacted directly to the wiring structure.

A light emitting device achieving a high heat dissipation effect and a high light utilization efficiency includes an aluminum substrate, a high heat dissipation ceramic layer on the aluminum substrate, an etching frame on the high heat dissipation ceramic layer, and a highly reflective ceramic layer on the high heat dissipation ceramic layer and the etching frame.

The present disclosure relates to a transparent substrate including: a resin pattern layer including a plurality of grooves respectively including side surfaces and a bottom surface; and, a conductive layer formed within the grooves, wherein a line width of the conductive layer is 0.1 μm to 3 μm and an average height of the conductive layer is 5% to 50% of a maximum depth of each of the grooves, and a manufacturing method thereof, such that simplicity in a manufacturing process and a consecutive process are enabled, manufacturing costs are inexpensive, and a transparent substrate having superior electrical conductivity and transparency characteristics is manufactured.

A method for milling flex foil includes providing a web (14) of flex foil including a substrate; a first conductive layer arranged on one surface of the substrate; a second conductive layer arranged on an opposite surface of the substrate; a first insulating layer arranged adjacent to the first conductive layer; and a second insulating layer arranged adjacent to the second conductive layer. The method includes dry milling one side of the web using a milling wheel (20-1) and a first cliche pattern (25-1) (including a rotating drum (24-1) and a flexible substrate (26-1)) including raised portions and non-raised portions to selectively remove at least one of the first conductive layer and the first insulating layer. The method includes dry milling an opposite side of the web using a milling wheel (20-2) and a second cliche pattern (25-2) including upper raised portions, lower raised portions and non-raised portions to selectively remove the second insulating layer.

A method for manufacturing a dual conductor laminated substrate includes providing a first laminate including a first insulating layer and a first conductive layer; defining a first trace pattern including one or more traces in the first laminate; providing a second laminate including a second insulating layer and a second conductive layer; defining a second trace pattern including one or more traces in the second laminate; defining access holes in the second insulating layer; at least one of depositing and stenciling a conductive material in the access holes of the second insulating layer; and aligning and attaching the first laminate to the second laminate to create a laminated substrate.