A die can be applied to a front conductive layer. Openings can be formed in the conductive layer over contact points on the die. The openings can be filled with a conductive material to electrically couple the conductive layer to the contact points on the die. The front conductive layer can be etched to form a first conductive pattern. Conductive standoffs can be formed on portions of the front conductive layer. An additional front conductive layer can be laminated onto the front side. Openings can be formed in the additional front conductive layer over the standoffs. The openings can be filled with a conductive material to electrically couple the additional conductive layer to the underlying standoffs. The additional conductive layer can be etched to form a second conductive pattern.

A module includes a ceramic multilayer substrate including a main surface; a surface-layer conductor pattern arranged on the main surface and integrally formed to include a land portion and an interconnection portion extending from the land portion; a first layer arranged to cover the land portion while exposing at least a part of the interconnection portion, the first layer having conductivity, the first layer being composed of a material that is lower in affinity to solder than a material for the surface-layer conductor pattern, and a component mounted on the first layer with solder being interposed. The solder is not in direct contact with the surface-layer conductor pattern.

A method of forming a solderable solder deposit on a contact pad, comprising the steps of providing an organic, non-conductive substrate which exposes said contact pad under an opening of a first non-conductive resist layer, depositing a conductive layer inside and outside the opening such that an activated surface results, thereby forming an activated opening, electrolytically depositing nickel or nickel alloy into the activated opening such that nickel/nickel alloy is deposited onto the activated surface, electrolytically depositing tin or tin alloy onto the nickel/nickel alloy, with the proviso that the electrolytic deposition of later steps results in an entirely filled activated opening, wherein the entirely filled activated opening is completely filled with said nickel/nickel alloy, or in the entirely filled activated opening the total volume of nickel/nickel alloy is higher than the total volume of tin and tin alloy, based on the total volume of the entirely filled activated opening.

A current introduction terminal includes a board made of resin. The board has a first face and a second face opposite each other. The board hermetically separates environments of different air pressures from each other. A plurality of through via holes corresponding both to a plurality of metal terminals of a first surface-mount connector to be mounted on the first face and to a plurality of metal terminals of a second surface-mount connector to be mounted on the second face are formed to penetrate between the first and second faces, and then hole parts of the through via holes are filled with resin.

Electronic substrates, contact pads for electronic substrates, and related methods are disclosed. Electronic substrates may include an electrically conductive layer that forms at least one contact pad and at least one metal trace on a non-conductive layer. The contact pads are arranged with greater thicknesses or heights above the non-conductive layer than the metal traces. Dielectric layers are disclosed that cover the metal traces while leaving top surfaces of the contact pads exposed. Top surfaces of the dielectric layers may be arranged to be coplanar with top surfaces of the contact pads to provide electronic substrates having generally planar top faces. Bottom faces of electronic substrates may include mounting pads that are coplanar with additional dielectric layers. Methods are disclosed that include forming dielectric layers to cover contact pads and metal traces, and removing surface portions of the dielectric layers until the contact pads are accessible through the dielectric layers.

A lamination circuit board structure lamination circuit board structure includes a printed circuit board substrate including conductive wiring traces on at least a first wiring face, a prepreg layer formed over the first wiring face, and a patch having an area smaller than 1,000 mm.sup.2. The patch includes conductive wiring traces formed on a wiring face and is laminated to the printed circuit board substrate over the prepreg layer, oriented with the wiring face in contact with and pressed into the prepreg layer. Portions of the prepreg layer fill interstices between the conductive wiring traces

Provided is a method for manufacturing a wiring board that forms a wiring layer having favorable adhesion without a resin resist pattern. A method prepares a substrate with seed-layer including: a underlayer on the surface of an insulating substrate; and a seed layer on the surface of the underlayer, the seed layer having a predetermined pattern and containing metal; presses a solid electrolyte membrane against the seed layer and the underlayer, and applies voltage between an anode and the underlayer to reduce metal ions in the membrane and form a metal layer on the surface of the seed layer; and removes an exposed region without the seed layer and the metal layer of the underlayer to form a wiring layer including the underlayer, the seed layer and the metal layer on the surface of the substrate.

Electronic substrates, contact pads for electronic substrates, and related methods are disclosed. Electronic substrates may include an electrically conductive layer that forms at least one contact pad and at least one metal trace on a non-conductive layer. The contact pads are arranged with greater thicknesses or heights above the non-conductive layer than the metal traces. Dielectric layers are disclosed that cover the metal traces while leaving top surfaces of the contact pads exposed. Top surfaces of the dielectric layers may be arranged to be coplanar with top surfaces of the contact pads to provide electronic substrates having generally planar top faces. Bottom faces of electronic substrates may include mounting pads that are coplanar with additional dielectric layers. Methods are disclosed that include forming dielectric layers to cover contact pads and metal traces, and removing surface portions of the dielectric layers until the contact pads are accessible through the dielectric layers.

Electronic substrates, contact pads for electronic substrates, and related methods are disclosed. Electronic substrates may include an electrically conductive layer that forms at least one contact pad and at least one metal trace on a non-conductive layer. The contact pads are arranged with greater thicknesses or heights above the non-conductive layer than the metal traces. Dielectric layers are disclosed that cover the metal traces while leaving top surfaces of the contact pads exposed. Top surfaces of the dielectric layers may be arranged to be coplanar with top surfaces of the contact pads to provide electronic substrates having generally planar top faces. Bottom faces of electronic substrates may include mounting pads that are coplanar with additional dielectric layers. Methods are disclosed that include forming dielectric layers to cover contact pads and metal traces, and removing surface portions of the dielectric layers until the contact pads are accessible through the dielectric layers.

A circuit board is disposed on a substrate and includes a dielectric layer and a circuit layer. The dielectric layer is disposed on the substrate. The circuit layer is embedded in the dielectric layer and has plural traces. Each of the traces has a first top surface and a first bottom surface which are opposite to each other, and the first bottom surface faces toward the substrate. The first top surface is exposed from the dielectric layer, and an area of a vertical projection of the first top surface on the substrate is smaller than an area of a vertical projection of the first bottom surface on the substrate.