Provided is a method for manufacturing a printed circuit board with electronic component; including: mounting an electronic component on an insulating substrate; applying an insulating first coating resin to at least a part of the electronic component; curing the first coating resin; applying an insulating second coating resin to the cured first coating resin; and curing the second coating resin.

A wiring substrate includes an insulating layer including resin and filler particles, and an embedded wiring layer including wirings and embedded in the insulating layer such that the wirings are filling grooves formed on a surface of the insulating layer, respectively. The embedded wiring layer is formed such that the inter-wiring distance between the closest two wirings of the wirings in the embedded wiring layer is in the range of 2 μm to 8 μm, and the insulating layer is formed such that the maximum particle size of the filler particles is 50% or less of the inter-wiring distance.

A power module is provided. The power module includes a substrate, a power conversion chip that is disposed on the substrate and an insulating film that is formed on a structure in which the power conversion chip is disposed on the substrate. Additionally, the power module includes a metal mold that encases the structure that is coated with the insulating film. Additionally, the power module provides a simplified structure and improved heat dissipation performance compared to conventional power modules.

An object of the present disclosure is to be able to further reduce the size of a substrate structure including a plurality of elements. The substrate structure includes: a base substrate that includes a first conductive plate and a second conductive plate; a first element connected to the first conductive plate and the second conductive plate; and a second element connected to the first conductive plate and the second conductive plate. The first conductive plate and the second conductive plate are disposed on the same plane on the base substrate in a state of being electrically insulated from each other, the first element is mounted on a first main surface of the base substrate, and the second element is mounted on a second main surface that is on the opposite side to the first main surface relative to the base substrate.

A composite wiring substrate includes a first wiring substrate including a first connection terminal, a second wiring substrate including a second connection terminal facing the first connection terminal, and a joint material joining the first connection terminal and the second connection terminal. The first outline of the first connection terminal is inside the second outline of the second connection terminal in a plan view. The joint material includes a first portion formed of an intermetallic alloy of copper and tin, and contacting each of the first connection terminal and the second connection terminal, and a second portion formed of an alloy of tin and bismuth, and including a portion between the first outline and the second outline in the plan view. The second portion contains the bismuth at a higher concentration than in the eutectic composition of a tin-bismuth alloy, and is separated from the second connection terminal.

A display device includes a display panel including a first area, a second area, and a bending area disposed between the first area and the second area, the bending area having a curvature radius, a data driver disposed on the display panel and overlapping the second area in a plan view, and a bending protection layer disposed on the display panel and the data driver and overlapping the first area in a plan view, the bending area, and the second area. The bending protection layer includes a thermochromic pigment having a light transmittance that varies according to a temperature.

A stackable via package includes a substrate having an upper surface and a trace on the upper surface, the trace including a terminal. A solder ball is on the terminal. The solder ball has a solder ball diameter A and a solder ball height D. A via aperture is formed in a package body enclosing the solder ball to expose the solder ball. The via aperture includes a via bottom having a via bottom diameter B and a via bottom height C from the upper surface of the substrate, where A<B and 0=<C<1/2×D. The shape of the via aperture prevents solder deformation of the solder column formed from the solder ball as well as prevents solder bridging between adjacent solder columns.

A wiring substrate includes an insulating layer including resin and filler particles, and an embedded wiring layer including wirings and embedded in the insulating layer such that the wirings are filling grooves formed on a surface of the insulating layer, respectively. The embedded wiring layer is formed such that the smallest line width of the wirings in the embedded wiring layer is in the range of 2 μm to 8 μm, and the insulating layer is formed such that the maximum particle size of the filler particles is 50% or less of the smallest line width of the wirings in the embedded wiring layer.

An electronic component module includes a plurality of components having terminals and arranged along a plane, a sealing resin portion that covers and seals these components and has a plane as one plane of an outer surface, and a shield layer that covers the outer surface of the sealing resin portion. Terminals of the plurality of components are exposed in a state of protruding from the plane of the sealing resin portion, and the terminals of these components protruding from the plane of the sealing resin portion are used as mounting terminals of the electronic component module.

A processor substrate includes: an electrically insulating material having a first main side and a second main side opposite the first main side; a plurality of electrically conductive structures embedded in the electrically insulating material and configured to provide an electrical interface at the first main side of the electrically insulating material and to provide electrical connections from the electrical interface to the second main side of the electrically insulating material; and a power device module embedded in the electrically insulating material and configured to convert a voltage provided at the second main side of the electrically insulating material and which exceeds a voltage limit of the processor substrate to a voltage that is below the voltage limit of the processor substrate. An electronic system that includes the processor substrate is also described.