An electronic device and manufacturing method thereof are disclosed. The manufacturing method of the electronic device comprises following steps: forming at least a thin-film conductive line on the substrate by a thin-film process; forming at least an electrical connection pad on the substrate by a printing process, wherein the electrical connection pad is electrically connected with the thin-film conductive line; and disposing at least an electronic element on the substrate, wherein the electronic element is electrically connected with the thin-film conductive line through the electrical connection pad. The electronic device has a lower manufacturing cost and a higher component configuration density, and the production yield and reliability of the electronic device are improved by the configuration of the electrical connection pad.

A chip part includes a substrate, a first electrode and a second electrode which are formed apart from each other on the substrate and a circuit network which is formed between the first electrode and the second electrode. The circuit network includes a first passive element including a first conductive member embedded in a first trench formed in the substrate and a second passive element including a second conductive member formed on the substrate outside the first trench.

A wiring board manufacturing method includes: forming a first groove structure in a first principal surface of a base by scanning with laser light in a first irradiation pattern such that the first groove structure has a first width; irradiating an inside of the first groove structure with laser light in a second irradiation pattern that is different from the first irradiation pattern to form recessed portions inside the first groove structure; and forming a first wiring pattern by filling the first groove structure with a first electrically-conductive material to form a first wiring pattern whose shape matches with a shape of the first groove structure in a top view.

A method for producing a wiring circuit board includes a step of preparing a substrate; a step of forming a metal layer on one side of the substrate in a thickness direction; a step of forming a first insulating layer on one side of the metal layer in the thickness direction; a step of forming a conductive pattern on one side of the first insulating layer in the thickness direction; a step of removing the substrate and exposing the metal layer; and a step of depositing a metal on the other side of the metal layer in the thickness direction and forming a first metal support layer. The first metal support layer has a terminal support portion supporting two terminals of a conductive pattern, a wiring support portion supporting a wiring of the conductive pattern, and a second wiring support portion supporting a second wiring of the conductive pattern.

A method for producing a flexible printed circuit board according to an embodiment of the present invention includes a through-hole formation step of preparing a base material including a base film having insulating properties and flexibility and a pair of metal films stacked on both surface sides of the base film, and forming a through-hole in the metal film on a front surface side of the base material and the base film; a filling step of stacking, by electroplating on a front surface of the base material, stacking a conductive material on a surface of the metal film on the front surface side to form a conductive material layer and to fill the through-hole with the conductive material; and a removal step of removing, by etching the front surface of the base material, a surface layer of the conductive material layer stacked on the surface of the metal film on the front surface side and a surface layer of the conductive material filling the through-hole.

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.

Disclosed are an ultra-thin copper foil with a carrier foil and a method for manufacturing an embedded substrate by using the same, the ultra-thin copper foil with a carrier foil including: a carrier foil; a non-etching release layer on the carrier foil; a first ultra-thin copper foil layer on the non-etching release layer; an etch stop layer on the first ultra-thin copper foil layer; and a second ultra-thin copper foil layer on the etch stop layer.

An electronic device and manufacturing method thereof are disclosed. The manufacturing method of the electronic device comprises following steps: forming at least a thin-film conductive line on the substrate by a thin-film process; forming at least an electrical connection pad on the substrate by a printing process, wherein the electrical connection pad is electrically connected with the thin-film conductive line; and disposing at least an electronic element on the substrate, wherein the electronic element is electrically connected with the thin-film conductive line through the electrical connection pad. The electronic device has a lower manufacturing cost and a higher component configuration density, and the production yield and reliability of the electronic device are improved by the configuration of the electrical connection pad.

A die and a substrate are provided. The die comprises at least one integrated circuit chip, and the substrate comprises first and second subsets of conductive pillars extending at least partially therethrough. Each of the first subset of conductive pillars comprises a protrusion bump pad protruding from a surface of the substrate, and the second subset of conductive pillars each partially form a trace recessed within the surface of the substrate. The die is coupled to the substrate via a plurality of conductive bumps each extending between one of the protrusion bump pads and the die.

Provided herein is a printed wiring board that can desirably dissipate the heat of a heat-generating component. The printed wiring board includes one or more wires, and one or more heat-generating components. The one or more wires include a rolled copper foil, either partly or as a whole. The one or more heat-generating components and the one or more wires are directly or indirectly connected to each other.