A circuit board having a plurality of conductive layers including a first conductive layer and a second conductive layer is provided. The circuit board includes a plurality of non-conductive layers in-between respective conductive layers of the plurality of conductive layers. The plurality of non-conductive layers include at least a first non-conductive layer disposed between the first conductive layer and the second conductive layer. At least one collapsed stud bump extends at least partially through the first non-conductive layer to electrically couple the first conductive layer to the second conductive layer.

The embodiment of the disclosure provides a composite layer circuit element and a manufacturing method thereof. The manufacturing method of the composite layer circuit element includes the following. A carrier is provided. A first dielectric layer is formed on the carrier, and the first dielectric layer is patterned. The carrier on which the first dielectric layer is formed is disposed on a first curved-surface mold, and the first dielectric layer is cured. A second dielectric layer is formed on the first dielectric layer. The second dielectric layer is patterned. The carrier on which the first dielectric layer and the second dielectric layer are formed is disposed on a second curved-surface mold, and the second dielectric layer is cured. A thickness of a projection of the first curved-surface mold is smaller than a thickness of a projection of the second curved-surface mold.

A method for manufacturing a wiring circuit board that is a double-sided wiring circuit board includes a first step of preparing a laminate and a second step. The laminate includes a metal core layer, insulating layer, and conductor layers. The insulating layer has a region and an opening that are adjacent to each other. The insulating layer has a region including a part facing the region in a thickness direction, and an opening adjacent to the region. The conductor layer includes a wiring portion and a conductive portion. The conductor layer includes a wiring portion and a conductive portion. In the second step, the first and second etching treatments for etching the metal core layer through the openings are carried out to form a via portion having a periphery surrounded by a space, extending between the regions, and connected to the conductive portions.

An electronic-component carrier board includes carrier plates formed in a stack, and insulating layers each disposed between two adjacent ones of the carrier plates. Multiple conductive pins extend through the insulating layers and the carrier plates. Multiple conductive wires equal in length and width are provided. Each conductive wire is connected to one of the conductive pins, covered by one of the insulating layers, disposed between two adjacent ones of the carrier plates, and extends outwardly from the stack of the carrier plates. A wiring method for the electronic-component carrier board is also disclosed.

[Object] Provided is a printed circuit board ensuring a degree of freedom in circuit design and unlikely to cause a circuit connection failure.

[Solving Means] A middle interlayer circuit 11, an upper surface side interlayer circuit 12, and a lower surface side interlayer circuit 13 are formed from a connection surface-less integral conductor. In addition, a connection surface 33 between the upper surface side interlayer circuit 12 and an upper surface side surface layer circuit 14 and a connection surface 34 between the lower surface side interlayer circuit 13 and a lower surface side surface layer circuit 15 lack a connection surface in a plate thickness direction, and thus a satisfactory connection state is achieved. Accordingly, a first circuit 10 is unlikely to cause a connection failure. In addition, the upper surface side interlayer circuit 12 and the lower surface side interlayer circuit 13 can be disposed at misaligned positions in the plane direction of the printed circuit board, and thus the degree of freedom in circuit design increases. Plane circuits 24 and 16 not connected to the first circuit can be disposed with insulating layers 31 and 32 sandwiched below the upper surface side interlayer circuit 12 or above the lower surface side interlayer circuit 13.

Provide are a method for manufacturing a wiring board or a wiring board material, and the wiring board obtained by the method, which allows columnar metal members to be inserted into the wiring board at once using a simple operation, enables alignment without requiring strict accuracy, can handle columnar metal members having different shapes, and imparts sufficiently high adhesive strength to the columnar metal members. The method includes the steps of: laminating a laminate material LM including the support sheet 10 having the columnar metal members 14 formed thereon, a wiring board WB or a wiring board material WB′ having a plurality of openings in portions corresponding to the columnar metal members 14, and a prepreg 16′ having a plurality of openings in portions corresponding to the columnar metal members 14 and containing a thermosetting resin such that the columnar metal members 14 are positioned in the respective openings; integrating the laminate material LM by heating and pressing to obtain a laminate LB including a thermosetting resin filled between an inner surface of each of the openings of the wiring board WB or the wiring board material WB′ and each of the columnar metal members 14; and peeling at least the support sheet 14 from the laminate LB.

A printed circuit board includes: a first insulating layer having a recess portion in one surface of the first insulating layer; a first circuit pattern embedded in the first insulating layer and being in contact with a lower surface of the recess portion; a second insulating layer disposed on the one surface of the first insulating layer to be disposed in at least a portion of the recess portion; and a via penetrating through at least a portion of the second insulating layer, disposed in the recess portion, and connected to the first circuit pattern.

A method of making an electrical component includes transmitting electrical energy from a power source through one or more deposition anodes, through an electrolyte solution, and to an intralayer electrical-connection feature of a build plate, such that material is electrochemically deposited onto the intralayer electrical-connection feature and forms an interlayer electrical-connection feature. The method also includes securing a dielectric material so that the dielectric material contacts and electrically insulates the intralayer electrical-connection feature and contacts and at least partially electrically insulates the interlayer electrical-connection feature. The method additionally includes depositing a seed layer onto the dielectric material and the interlayer electrical-connection feature, electrochemically depositing material onto the seed layer, to form at least one second intralayer electrical-connection feature of the electrical component, and removing any one or more portions of the seed layer onto which no portion of the at least one second intralayer electrical-connection feature is formed.

A method of attaching a chip to the substrate with an outer layer comprising via pillars embedded in a dielectric such as solder mask, with ends of the via pillars flush with said dielectric, the method comprising the steps of: (o) optionally removing organic varnish, (p) positioning a chip having legs terminated with solder bumps in contact with exposed ends of the via pillars, and (q) applying heat to melt the solder bumps and to wet the ends of the vias with solder.

A method of manufacturing a printed circuit board includes forming an intermediate layer on a first conductive layer disposed on a first insulating layer, forming a second conductive layer and a second insulating layer on the intermediate layer, separating the first insulating layer from at least one portion of the first conductive layer, and etching the first conductive layer and the intermediate layer. After the etching, a surface of the second conductive layer protrudes further than a surface of the second insulating layer. The intermediate layer before the etching includes a portion overlapping the second conductive layer in a vertical direction and another portion not overlapping the second conductive layer in the vertical direction.