A multilayer printed circuit board is provided having a first conductive layer and a first plating resist selectively positioned within the first conductive layer. A second plating resist may be selectively positioned within a second conductive layer. A through hole extends through the first plating resist in the first conductive layer and the second plating resist in the second conductive layer. An interior surface of the through hole is plated with a conductive material except along a length between the first plating resist and the second plating resist. This forms a partitioned plated through hole having a first via segment electrically isolated from a second via segment.

A circuit board is provided in which a transmission loss is reduced. The circuit board includes a first layer; a transmission line disposed on the first layer; and a second layer stacked with the first layer. The second layer includes a first region, which is constructed of a first material, corresponding to a position of the transmission line, and a second region, which is constructed of a second material having a permittivity that is different from that of the first material, corresponding to the position of the transmission line.

Substrates configured to route electrical signals may include a first dielectric material and an electrically conductive material located on a first side of the first dielectric material. A second dielectric material may be located on a second, opposite side of the first dielectric material. A series of voids may be defined by the second dielectric material extending from the first dielectric material at least partially through the second dielectric material. Footprints of at least some of the voids of the series of voids may at least partially laterally overlap with the electrically conductive material.

Provided is a circuit board, a signal crosstalk suppression method, a storage medium and an electronic device. The circuit board includes: a circuit board body, provided with a signal via-hole structure, a ground via-hole structure and a slotted structure; the signal via-hole structure is configured to transmit a signal by changing a layer, and the ground via-hole structure is configured to return a signal transmitted from the signal via-hole structure; the slotted structure is provided between the signal via-hole structure and the ground via-hole structure, and configured to suppress a signal crosstalk of the signal via-hole structure.

Provided is a SiC semiconductor element equipped with a SiC integrated circuit having a stable characteristic, which operates normally even in a radiation environment. A radiation resistant circuit device includes: a SiC semiconductor element equipped with a SiC integrated circuit, a printed board on which the SiC semiconductor element is provided, a conductive wiring that is arranged inside the printed board and has a predetermined surface facing a bottom surface of a substrate electrode of the SiC integrated circuit, and an insulating material arranged between the bottom surface of the substrate electrode of the SiC integrated circuit and the predetermined surface of the conductive wiring.

A carrier structure is provided. A spacer is formed in an insulation board body provided with a circuit layer, and is not electrically connected to the circuit layer. The spacer breaks the insulation board body, and a structural stress of the insulation board body will not be continuously concentrated on a hard material of the insulation board body, thereby preventing warpage from occurring to the insulation board body.

Systems and methods are provided for reducing crosstalk between differential signals in a printed circuit board (PCB) using fine pitch vias. A pair of contact pads are on the top surface of the PCB and configured to couple a PCB component to the PCB, the contacts a first distance from each other. A first via of a plurality of vias is electrically coupled to a first contact of the pair of contacts and a second via is electrically coupled to a second contact, the first via and second via a second distance from each other, the second distance being less than current standards for minimum via pitch. Each via comprises a via pad on the top surface and a plated through-hole extending from the top surface to a termination point. A separator gap is between the first via and the second via.

A printed circuit board is disclosed. The printed circuit board includes a first substrate portion, and a second substrate portion connected to the first substrate portion and having a flexible insulation layer which is bendable, and the second substrate portion includes a frame member inserted into the flexible insulation layer.

A method of creating thermal boundaries in a substrate is provided. The method includes forming the substrate with first and second sections to be in direct thermal communication with first and second thermal elements, respectively, machining, in the substrate, first and second cavities for defining a third section of the substrate between the first and second sections and disposing a material having a characteristic thermal conductivity that is substantially less than that of the ceramic in the first and second cavities.

In an electro-optical device, a flexible first wiring substrate and a flexible second wiring substrate, which are respectively coupled to a first terminal region and a second terminal region, extend while overlapping with each other, and a first mold material is provided between the first wiring substrate and the second wiring substrate. The second wiring substrate includes a base film having transmissivity, a wiring line provided at the base film, and a protective layer that covers the wiring line and is less transmissive than the base film. In the second wiring substrate, a light-transmission window in which the wiring line and the protective layer are not present in part is provided in a region thereof overlapping with the first mold material.