A filter circuit includes: a wiring pattern provided in an upper wiring layer of a printed circuit board, a wiring pattern provided in a lower wiring layer of the printed circuit board, a wiring pattern extending from one end of the wiring pattern, a wiring pattern provided so as to partially face the wiring pattern in the upper wiring layer, a bypass capacitor provided in the upper wiring layer and connected to the wiring pattern and a ground conductor surface, a via connecting one end of the wiring pattern and the wiring pattern, and a via connecting the wiring pattern and the wiring pattern. A structure including the wiring pattern, the via, and the wiring pattern faces a structure including the via and the wiring pattern.

An optical device may include an optical subassembly and a digital signal processor (DSP). The optical device may include a radio frequency (RF) interconnect that electrically connects the optical subassembly and the DSP. The optical device may include a passive RF filter on one or more transmission lines of the RF interconnect.

A glass core wiring substrate incorporating a high-frequency filter having good high-frequency characteristics as a core material and allowing a more efficient arrangement of a conductor in the glass substrate, a module including the same, and a method of manufacturing the glass core wiring substrate incorporating a high-frequency filter. A conductive layer in a glass through a hole in a glass core substrate has a structure in which a hollow cylindrical conductor layer on a side wall of the glass through hole is connected to a cover conductor layer covering one of two openings of the glass through hole. To achieve such a structure, a carrier is attached to one surface of the glass core substrate to cover one of the openings of the glass through hole, and the carrier is peeled off and removed after lamination of the conductor.

A wiring board includes a base material, a through hole that is formed in the base material, a magnetic member that is embedded in the through hole, and a plating film that covers end faces of the magnetic member exposed from the through hole. The magnetic member includes a conductor wire that is covered by a magnetic body. A wiring board manufacturing method includes forming a through hole in a base material, forming a magnetic member by covering a conductor wire by a magnetic body, embedding the magnetic member in the through hole, and forming a plating film that covers end faces of the magnetic member exposed from the through hole.

A multilayer electronic device may include a plurality of dielectric layers and a signal path having an input and an output. An inductor may include a conductive layer formed on one of the plurality of dielectric layers and may be electrically connected at a first location with the signal path and electrically connected at a second location with at least one of the signal path or a ground. The inductor may include an outer perimeter that includes a first straight edge facing outward in a first direction and a second straight edge parallel to the first straight edge and facing outward in the first direction. The second straight edge may be offset from the first straight edge by an offset distance that is less than about 500 microns and less than about 90% of a first width of the inductor in the first direction at the first straight edge.

A surface mountable coupler may include a monolithic base substrate having a first surface, a second surface, a length in an X-direction, and a width in a Y-direction that is perpendicular to the X-direction. A plurality of ports may be formed over the first surface of the monolithic base substrate including a coupling port, an input port, and an output port. The coupler may include a first thin film inductor and a second thin film inductor that is inductively coupled with the first thin film inductor and electrically connected between the input and output ports. A thin film circuit may electrically connect the first thin film inductor with the coupling port. The thin film circuit may include at least one thin film component.

Disclosed are an embedded circuit board and a fabrication method therefor. The embedded circuit board comprises: a circuit board body; signal transmission layers (1200), wherein the signal transmission layers are arranged on two opposite sides of the circuit board body; bonding layers, wherein the bonding layers are arranged between at least one signal transmission layer and the circuit board body and used for bonding the signal transmission layer to the circuit board body; metal bases which are embedded in the circuit board body and are electrically connected to the signal transmission layers on two opposite sides of the circuit board body; conductive parts which are arranged at the positions in the bonding layers corresponding to the metal bases, and are electrically connected to the signal transmission layer and the metal bases; and magnetic cores embedded in the circuit board body.

In an electronic component, a terminal electrode has a thickest portion and a part thinner than the thickest portion. Accordingly, an increase in solder fillet forming region occurs when the electronic component is solder-mounted onto a predetermined mounting substrate. In the electronic component, mounting strength is improved as a result of the increase in solder fillet forming region. In addition, in the electronic component, the thickest portion overlaps a bump electrode in a direction orthogonal to the lower surface of an element body. Accordingly, the impact that is applied to the electronic component during the mounting onto the mounting substrate is reduced and the impact resistance of the electronic component is improved.

One aspect provides a printed circuit board (PCB). The PCB includes a transmission line to transmit signals of a desired frequency, a first stub coupled to the transmission line at a first location, and a second stub coupled to the transmission line at a second location. The first stub is to filter out signals of a first frequency, the second stub is to filter out signals of a second frequency, and the first and second stubs are positioned such that an insertion loss of the transmitted signals of the desired frequency is substantially minimized.

A substrate includes a multilayer substrate body in which a plurality of circuit bodies are laminated in a laminating direction through insulating layers and are interlayer connected via a connected conductor formed on each of the insulating layers, and a magnetic body that is arranged in the laminating direction while at least a part of or all of the magnetic body sandwiches the circuit bodies. Each of the circuit bodies includes at least a first circuit body and a second circuit body. The first circuit body is formed of a first extending portion and a first folding portion. The second circuit body is formed of a second extending portion and a second folding portion.