The present invention comprises: a base film on which a first element mounting part and a second element mounting part are defined; wiring patterns formed by extending from each of the first element mounting part and the second element mounting part on the base film, wherein the wiring patterns include a first terminal part in the first element mounting part and a second terminal part in the second element mounting part; and a first plating layer formed on the second terminal part, wherein the first plating layer includes a pure metal plating layer, and the first plating layer is not formed on the first terminal part.

A conductive fabric includes a fabric with one or more electrically conductive wire braids woven into the fabric. The one or more wire braids are woven into the fabric such that one or more portions of each wire braid are exposed at one or more surfaces of the fabric, the exposed portions of the wire braid forming connection pads. Each connection pad provides an electrical connection point for attachment to a complementary electrical connection point on an electronic component, such as a bond pad, solder bump, or connection lead. A single wire braid can be used to electrically interconnect multiple electronic components. Multiple wire braids can be arranged, with appropriate spacing and alignment of exposed portions, to electrically interconnect multiple electronic components with multiple electrical interconnects between one or more electronic components. Each electrically conductive wire braid includes a plurality of individual electrically conductive wires braided together.

A printed wiring board for camera module includes: first and second mounting regions for first and second image pickup devices respectively provided on one and the other sides in a front surface of the printed wiring board, the first and second mounting regions respectively provided with first and second conductive patterns configured to be electrically connected to the first and second image pickup devices, respectively, and a component mounting region provided between the first mounting region and the second mounting region, the component mounting region provided with a third conductive pattern, the third conductive pattern configured to be electrically connected to a signal processing component, amounting density of the third conductive pattern in the component mounting region being higher than that of the first conductive pattern in the first mounting region or a mounting density of the second conductive pattern in the second mounting region, in a plan view.

An electronic device, and methods of manufacturing the same are disclosed. The method of manufacturing the electronic device includes forming a first metal layer on a first substrate, forming an integrated circuit or a discrete electrical component on a second substrate, forming electrical connectors on input and/or output terminals of the integrated circuit or discrete electrical component, forming a second metal layer on the first metal layer, the second metal layer improving adhesion and/or electrical connectivity of the first metal layer to the electrical connectors on the integrated circuit or discrete electrical component, and electrically connecting the electrical connectors to the second metal layer.

A surface finish for a printed circuit board (PCB) and semiconductor wafer includes a nickel disposed over an aluminum or copper conductive metal surface. A barrier layer including all or fractions of a nitrogen-containing molecule is deposited on the surface of the nickel layer to make a barrier layer/electroless nickel (BLEN) surface finish. The barrier layer allows solder to be reflowed over the surface finish. Optionally, gold (e.g., immersion gold) may be coated over the barrier layer to create a nickel/barrier layer/gold (NBG) surface treatment. Presence of the barrier layer causes the surface treatment to be smoother than a conventional electroless nickel/immersion gold (ENIG) surface finish. Presence of the barrier layer causes a subsequently applied solder joint to be stronger and less subject to brittle failure than conventional ENIG.

An electronic component includes a main body including a first surface, a first electrode and a second electrode arranged on the first surface, and a resist film arranged to isolate the first electrode from the second electrode. The first electrode and the second electrode are mainly composed of a first material. The first electrode includes a first portion including a central portion and having a first thickness and a second portion having a second thickness smaller than the first thickness in at least a part of a peripheral portion. The first portion is covered with a plated film where a film made of a second material higher in affinity for solder than the first material is exposed at an outermost surface. At least a part of the second portion is covered with the resist film. The first portion is distant from the resist film.

According to an embodiment, a flexible circuit board includes: a first substrate; a second substrate disposed on the first substrate and including an opening; a first conductive pattern part disposed on a bottom surface of the first substrate; a second conductive pattern part disposed on a top surface of the second substrate; a third conductive pattern part disposed between the first substrate and the second substrate; and an upper protective layer partially disposed on the second conductive pattern part and including a first open region, wherein the third conductive pattern part includes: a first inner lead pattern part disposed in the opening of the second substrate; and a first extension pattern part connected to the first inner lead pattern part, the second conductive pattern part includes: a second inner lead pattern part disposed in the first open region of the upper protective layer; and a second extension pattern part connected to the second inner lead pattern part, and a number of first inner lead pattern parts is greater than a number of second inner lead pattern parts.

A surface finish for a printed circuit board (PCB) and semiconductor wafer includes a nickel disposed over an aluminum or copper conductive metal surface. A barrier layer including all or fractions of a nitrogen-containing molecule is deposited on the surface of the nickel layer to make a barrier layer/electroless nickel (BLEN) surface finish. The barrier layer allows solder to be reflowed over the surface finish. Optionally, gold (e.g., immersion gold) may be coated over the barrier layer to create a nickel/barrier layer/gold (NBG) surface treatment. Presence of the barrier layer causes the surface treatment to be smoother than a conventional electroless nickel/immersion gold (ENIG) surface finish. Presence of the barrier layer causes a subsequently applied solder joint to be stronger and less subject to brittle failure than conventional ENIG.

A printed wiring board includes a base film having insulation properties and a conductive pattern including multiple wiring portions laminated so as to run on at least one surface of the base film, wherein each wiring portion includes a first conductive portion and a second conductive portion coating an outer surface of the first conductive portion, wherein an average width of each wiring portion is 10 m or greater to 50 m or smaller, and an average thickness of the second conductive portion is 1 m or greater to smaller than 8.5 m. A method for manufacturing a printed wiring board includes a first conductive portion forming step of forming a first conductive portion forming each wiring portion by plating an opening of the resist pattern on the conductive foundation layer, a conductive foundation layer removing step, and a second conductive portion coating step.

A printed circuit board according to an embodiment of the present invention includes a base film having an insulating property and a conductive pattern disposed on at least one surface of the base film. The conductive pattern includes a copper particle bond layer which is fixed to the base film, and a lightness L* of a conductive pattern non-formed region of the base film is 60 or less. The base film may include a modified layer on one surface side thereof.