An impedance matching structure is disposed on a circuit board for matching an impedance of a transmission line for transmitting an electronic signal. The structure includes: at least two redundant conducting sections coupled to different points between an input terminal and an output terminal of the transmission line, wherein the redundant conducting sections are apart from one another, and a first terminal of each of the redundant conducting sections is coupled to the transmission line, while a second terminal of each of the redundant conducting sections is apart from the transmission line; and at least one grounded conducting section, each of which corresponds to one of the redundant conducting sections, and surrounds in separation from the corresponding redundant conducting section, wherein each of the at least two redundant conducting sections is disposed in a corresponding plating hole.

A method for forming a Z-directed component for insertion into a mounting hole in a printed circuit board according to one example includes filling a first cavity having a tapered surface with a body material. A first layer of a constraining material is provided on top of the first cavity and has a second cavity having a width that is smaller than the first cavity. The second cavity is filled with the body material. Successive layers of the constraining material are provided on top of the first layer of the constraining material. Cavities of the successive layers of the constraining material are selectively filled with at least the body material to form layers of the main body portion of the Z-directed component. The constraining material is dissipated to release the Z-directed component from the constraining material and the Z-directed component is fired.

An interconnection substrate includes: a substrate having a first surface and a second surface opposite the first surface; and a transmission line including two parallel through-hole interconnections that are exposed to the first and second surfaces and are formed inside the substrate. Also, at least one of the two through-hole interconnections includes a narrow portion having a smaller diameter than a diameter of the through-hole interconnection in the first surface and a diameter of the through-hole interconnection in the second surface.

A radio frequency module is provided. A matching circuit includes an inductor which is connected in series to the power amplifier and is formed in a substrate. The substrate includes a ground layer, a low permittivity portion, and a high permittivity portion. The ground layer at least partially overlaps with a first input terminal of the low-noise amplifier in a plan view from a thickness direction of the substrate. The low permittivity portion at least partially overlaps with the first input terminal in a plan view from the thickness direction, and is provided between the first input terminal and the ground layer. The high permittivity portion is in contact with the inductor and has the permittivity greater than the permittivity of the low permittivity portion.

Embodiments of the present disclosure are directed toward techniques and configurations for electrical signal absorption in an interconnect stub. In one instance, a printed circuit board (PCB) assembly may comprise a substrate and an interconnect (such as a via) formed in the substrate to route an electrical signal within the PCB. The interconnect may include a stub formed on the interconnect. At least a portion of the stub may be covered with an absorbing material to at least partially absorb a portion of the electric signal that is reflected by the stub. The absorbing material may be selected such that its dielectric loss tangent is greater than one, for a frequency range of a frequency of the reflected portion of the electric signal. A dielectric constant of the absorbing material may be inversely proportionate to the frequency of the reflected electric signal. Other embodiments may be described and/or claimed.

A grounding structure of the high-frequency circuit board includes a dielectric substrate, a back surface ground electrode, an upper ground electrode, and a microstripline upper electrode. The dielectric substrate has a first surface and a second surface, and is provided with a first through-hole. A first opening of the first through-hole at the first surface is smaller than a second opening of the first through-hole at the second surface. A first grounding conductor layer is provided in the first through-hole. The back surface ground electrode is provided at the second surface and is connected with the first grounding conductor layer. The upper ground electrode is provided at the first surface and is connected with the first ground conductor layer. The microstripline upper electrode is provided at the first surface.

A printed circuit board has a double-sided substrate with an insulation layer, a bonding member, a base layer of an aluminum material, and a circuit pattern; a second insulation layer; a second bonding member; a second base layer; a through hole; a zinc substitution layer; a plating layer; and a second circuit pattern.

A circuit board includes a board base with a first surface and a second surface that is located opposite the first surface. A plurality of first coupling pads are located on the first surface of the board base. A plurality of second coupling pads are located on the second surface of the board base. The first coupling pads and the second coupling pads define a coupling pad footprint. A breakout via system is included in the board base. The breakout via system includes a plurality of primary signal vias that are located in the board base and outside of the coupling pad footprint, a plurality of first primary signal via connections that extend between the primary signal vias and the plurality of first coupling pads, and a plurality of second primary signal via connections that extend between the primary signal vias and the plurality of second coupling pads.

A printed circuit board includes a plurality of layers including attachment layers and routing layers; and columns of via patterns formed in the plurality of layers, wherein via patterns in adjacent columns are offset in a direction of the columns, each of the via patterns comprising: first and second signal vias forming a differential signal pair, the first and second signal vias extending through at least the attachment layers; and at least one conductive shadow via located between the first and second signal vias of the differential pair. In some embodiments, at least one conductive shadow via is electrically connected to a conductive surface film.

A co-axial structure includes a substrate, a first conductive structure, a second conductive structure, and an insulating layer. The substrate includes a first surface. The first conductive structure includes a first circuit deposited on the first surface and a first via penetrating the substrate. The second conductive structure includes a second circuit deposited on the first surface and a second via penetrating the substrate. The first via and the second via extend along a first direction. The first circuit and the second circuit extend along a second direction, and the second direction is perpendicular to the first direction. The insulating layer is located between the first via and the second via. The first conductive structure and the second conductive structure are electrically insulated. The first circuit and the second circuit are coplanar.