[Problem] To achieve a wiring board capable of suppressing the difference in the amount of delay between two signal wirings constituting differential signal wirings, while securing flexibility in design.

[Solution] A wiring board is configured to include a first insulating layer 1, a first signal wiring 2 and a second signal wiring 3. The first insulating layer 1 includes fibers 4 having the long axis in a first direction and aligned approximately parallel to each other at a first interval and an insulating material 5 filling gaps between the fibers 4 of the first direction. The first signal wiring 2 is formed approximately parallel to the first direction on the first insulating layer 1. The second signal wiring 3 is formed parallel to the first signal wiring 2 such that the interval between the first and second signal wirings 2 and 3 be approximately an integral multiple of the first interval, and the second signal wiring 3 transmits a differential signal of a signal transmitted on the first signal wiring 2.

A semiconductor device, a circuit board structure and a manufacturing forming thereof are provided. A circuit board structure includes a core layer, a first build-up layer and a second build-up layer. The first build-up layer and the second build-up layer are disposed on opposite sides of the core layer. The circuit board structure has a plurality of stress releasing trenches extending into the first build-up layer and the second build-up layer.

The invention relates to a circuit arrangement, comprising at least one wiring carrier plate (1), characterized by at least one separating element (2) formed in the wiring carrier plate (1), which separating element divides the wiring carrier plate (1) into sections separated by the separating element (2), wherein the transfer of vibrations from one section to another section is at least partially decoupled and/or damped by the separating element (2). The invention further relates to a converter having such a circuit arrangement, and to an aircraft having a converter. The converter can comprise capacitor stacks (3) arranged on the wiring carrier plate (1), and power semiconductors (6).

An integrated circuit chip carrier includes a wall surrounding a cavity. The wall includes one or more levels where each level is formed from a layer of a resin around a block. The block is made of a material different from the resin. The block is removed to open the cavity.

A capacitor device to store electrical charge is disclosed that includes a first unit of a first conductor layer fabricated from a first material. The first conductor layer is sandwiched between two dielectric layers. This assembly is layered on a second unit of a second conductor layer fabricated from a second material and sandwiched between two additional dielectric layers. The first conductor layers are all electrically connected to one another, and the second conductor layers being electrically connected to one another but are not electrically connected to the first conductor. Any multiple of first and second units may be utilized.

A method of manufacturing a circuit board having waveguides including forming a waveguiding structure by injection molding. The waveguiding structure includes a plurality of waveguides arranged at intervals and at least one connecting portion connecting two adjacent waveguides. Each waveguide includes a waveguiding substrate and at least one protrusion on the waveguiding substrate. The connecting portion is removed to obtain at least two waveguides. A metal layer is formed to wrap the whole outer surface of each waveguide. A plurality of receiving grooves is formed to penetrate a wiring board. Each waveguide wrapped by the metal layer is embedded in one of the receiving grooves. The waveguides and the wiring board are fixed. A portion of the metal layer on a surface of each protrusion facing away from the waveguiding substrate is removed. A circuit board is also provided.

An electronic functional member according to the present embodiment includes a substrate; a fiber mesh comprising a fibrous resin composition that extends onto and is connected to the substrate; and a patterned conductive coating portion that coats one surface of a portion of the fiber mesh and that also extends onto the substrate.

A method for manufacturing a circuit board is disclosed. An inner wiring base board with a first opening is provided. A base board is fixed in the first opening, and a first wiring base board and a second wiring base board are pressed on opposite surfaces of the inner wiring base board. The base board is made of ceramic and has a high light reflectivity of 92% to 97%. A first conductor layer and a second conductor layer are formed on opposite surfaces of the laminated structure. The first conductor layer includes a plurality of connecting pads on the base board. A solder mask is formed on an outer side of the first conductor layer, the solder mask has a high light reflectivity of 92% to 95%, and the base board is exposed outside the solder mask.

A method for manufacturing an electronic device is disclosed. The electronic device has a first region and a transparent region. The method includes the steps of providing a substrate, forming an electric circuit layer on the substrate at an elevated temperature, forming an opening in the transparent region and penetrating through a portion of the electric circuit layer, forming a light emitting unit on the electric circuit layer in the first region, and forming an insulating layer on the substrate. At least a part of the insulating layer is formed in the opening.

An electronic element mounting substrate includes: a first substrate including a first principal face; a second substrate located inside the first substrate in a plan view of the electronic element mounting substrate, the second substrate being made of a carbon material; a third substrate located between the first substrate and the second substrate in the plan view, the third substrate being made of a carbon material; and a first mounting portion for mounting a first electronic element, the first mounting portion being located on the first principal face side in a thickness direction of the substrate. The second substrate and the third substrate each have a low heat conduction direction and a high heat conduction direction. The second substrate and the third substrate is arranged so that the low heat conduction directions thereof are perpendicular to each other, and the high heat conduction directions thereof are perpendicular to each other.