A manufacturing method of an interposed substrate is provided. A metal-stacked layer comprising a first metal layer, an etching stop layer and a second metal layer is formed. A patterned conductor layer is formed on the first metal layer, wherein the patterned conductor layer exposes a portion of the first metal layer. A plurality of conductive pillars is formed on the patterned conductor layer, wherein the conductive pillars are separated from each other and stacked on a portion of the patterned conductor layer. An insulating material layer is formed on the metal-stacked layer, wherein the insulating material layer covers the portion of the first metal layer and encapsulates the conductive pillars and the other portion of the patterned conductor layer. The metal-stacked layer is removed to expose a lower surface opposite to an upper surface of the insulating material layer and a bottom surface of the patterned conductor layer.

A manufacturing method of an interposed substrate is provided. A metal-stacked layer comprising a first metal layer, an etching stop layer and a second metal layer is formed. A patterned conductor layer is formed on the first metal layer, wherein the patterned conductor layer exposes a portion of the first metal layer. A plurality of conductive pillars is formed on the patterned conductor layer, wherein the conductive pillars are separated from each other and stacked on a portion of the patterned conductor layer. An insulating material layer is formed on the metal-stacked layer, wherein the insulating material layer covers the portion of the first metal layer and encapsulates the conductive pillars and the other portion of the patterned conductor layer. The metal-stacked layer is removed to expose a lower surface opposite to an upper surface of the insulating material layer and a bottom surface of the patterned conductor layer.

Provided herein is a method for forming a transparent electrode film for display and the transparent electrode film for display, the method comprising forming an electrode pattern by printing a fine electrode pattern on a release film using a conductive ink composition; forming an insulating layer by applying an insulating resin on the release film on which the electrode pattern has been formed; forming a substrate layer by laminating a substrate on the insulating layer; and removing the release film.

Provided herein is a conductive pattern making method and conductive pattern, the method including forming a groove such that its width in an inlet area is bigger than its width in an inner area; filling the groove with a conductive ink composition; and drying the conductive ink composition so that a solvent contained in the conductive ink composition inside the groove is volatilized to reduce the volume of the conductive ink composition.

Disclosed is a circuit board having a contact pad for connection with an external device, which protrudes from an upper surface of an outermost insulating layer. A device can be mounted on the circuit board, and a connection terminal of the device can be connected to the contact pad of the circuit board by a wire etc.

Disclosed is a circuit board having a contact pad for connection with an external device, which protrudes from an upper surface of an outermost insulating layer. A device can be mounted on the circuit board, and a connection terminal of the device can be connected to the contact pad of the circuit board by a wire etc.

An electronic device includes a substrate and a flexible printed circuit board. The substrate includes a plurality of first pins disposed on the substrate. The flexible printed circuit board includes a plurality of second pins disposed on the flexible printed circuit board. The first pins and the second pins are bonded to each other to form a plurality of bonding points. The bonding points include at least one central bonding point and at least one first bonding point. The at least one central bonding point is located in a central area of the electronic device. The at least one first bonding point is located in a first area of the electronic device. The first area is located outside the central area. A line width of the at least one first bonding point is greater than a line width of the at least one central bonding point.

An electronic device includes a substrate and a flexible printed circuit board. The substrate includes a plurality of first pins disposed on the substrate. The flexible printed circuit board includes a plurality of second pins disposed on the flexible printed circuit board. The first pins and the second pins are bonded to each other to form a plurality of bonding points. The bonding points include at least one central bonding point and at least one first bonding point. The at least one central bonding point is located in a central area of the electronic device. The at least one first bonding point is located in a first area of the electronic device. The first area is located outside the central area. A line width of the at least one first bonding point is greater than a line width of the at least one central bonding point.

A printed circuit board includes a printed wiring board including an insulative substrate having a first surface and a second surface opposite to the first surface, and wiring provided on the second surface of the insulative substrate to face the through-holes. The insulative substrate has flexibility and through-holes passing through the insulative substrate from the first surface to the second surface. A semiconductor element is mounted on the first surface of the insulative substrate of the printed wiring board and has element terminals interposed between the printed wiring board and the semiconductor element. Conductive members filled in the through-holes connect the element terminals and the wiring. The insulative substrate has elasticity in which an elongation percentage of the insulative substrate is 20% or more. The wiring is formed from a conductive polymer or an elastic conductive paste in which conductive particles are mixed into a resin material.

A printed circuit board includes a printed wiring board including an insulative substrate having a first surface and a second surface opposite to the first surface, and wiring provided on the second surface of the insulative substrate to face the through-holes. The insulative substrate has flexibility and through-holes passing through the insulative substrate from the first surface to the second surface. A semiconductor element is mounted on the first surface of the insulative substrate of the printed wiring board and has element terminals interposed between the printed wiring board and the semiconductor element. Conductive members filled in the through-holes connect the element terminals and the wiring. The insulative substrate has elasticity in which an elongation percentage of the insulative substrate is 20% or more. The wiring is formed from a conductive polymer or an elastic conductive paste in which conductive particles are mixed into a resin material.