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 functional panel, a method of manufacturing the same, and a terminal are disclosed. The functional panel includes a base substrate, at least one differential signal line group on the base substrate, where each differential signal line group of the at least one differential signal line group includes two signal lines and at least one ground line group on the base substrate and on the same side of the base substrate as the at least one differential signal line group. Each ground line group of the at least one ground line group includes two ground lines. Each ground line group corresponds to each differential signal line group one-to-one, and orthographic projections of the two ground lines in each ground line group on the base substrate are on both sides of an orthographic projection of a corresponding differential signal line group on the base substrate, and two ground lines in the ground line group are connected to a same reference ground.

The present invention uses a photolithography process and an electroplating process to perform. TAV copper filling and patterning of the fabrication of the double side copper-plated layers to plate the double side copper-plated layers in advance at the TAV through holes to serve as a stress buffer layer of the aluminum nitride substrates. Then the subsequent pattern designs of the copper-plated layers are customized. According to the simulation theory calculations, it is proved that the stress which accumulates on the short-side of the copper-plated layer of the aluminum nitride substrate with the asymmetric structure may be effectively reduced to facilitate the improvement of the reliability of the aluminum nitride substrate.

A component carrier includes an electrically insulating layer structure having a first main surface and a second main surface with a through hole extending through the electrically insulating layer structure between the first main surface and the second main surface. An electrically conductive bridge structure connects opposing sidewalls of the electrically insulating layer structure delimiting the through hole. A vertical thickness of the electrically insulating layer structure is not more than 200 m and a narrowest vertical thickness of the bridge structure is at least 20 m.

A flexible printed circuit board includes a base film having an insulating property, and multiple interconnects laminated to at least one surface side of the base film. The multiple interconnects include a first interconnect and a second interconnect in a same plane. An average thickness of the second interconnect is greater than an average thickness of the first interconnect. A ratio of the average thickness of the second interconnect to the average thickness of the first interconnect is greater than or equal to 1.5 and less than or equal to 50.

A flexible printed circuit board includes a base film having an insulating property, and one or more interconnects laminated to at least one surface side of the base film. At least one of the one or more interconnects includes, in a longitudinal direction, a first portion and a second portion that is a portion other than the first portion, an average thickness of the second portion being greater than an average thickness of the first portion. A ratio of the average thickness of the second portion to the average thickness of the first portion is greater than or equal to 1.5 and less than or equal to 50.

A wiring circuit board includes an insulating layer and a conductive layer disposed on a front surface of the insulating layer. The conductive layer includes a first wiring, a first terminal electrically connected to the first wiring, a second wiring independent of the first wiring and having a thick thickness T2 with respect to a thickness T1 of the first wiring, and a second terminal electrically connected to the second wiring. The surfaces of the first terminal and the second terminal are disposed at generally the same position in a thickness direction.

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 component carrier includes a stack having at least one electrically conductive layer structure and/or at least one electrically insulating layer structure, at least one first electrically conductive track extending from a vertical level defined by one of the layer structures up to a first height, at least one second electrically conductive track extending from the vertical level defined by the one of the layer structures up to a second height being larger than the first height, and at least one further electrically insulating layer structure in which the at least one first electrically conductive track and the at least one second electrically conductive track are embedded.