A multilayer circuit board includes a laminate of insulating layers, conductive patterns each provided at an interlayer in the laminate, a via conductor extending through at least one of the insulating layers, and external terminals on a lower main surface of the laminate. A shield electrode layer connected to a ground potential is provided on at least one side surface of the laminate. At least one surrounding conductive pattern surrounding an element to be shielded is provided at an interlayer between corresponding ones of the insulating layers. Both ends of the surrounding conductive pattern are connected to the shield electrode layer.

Micro-scale planar-coil transformers including one or more shields are disclosed. The one or more shields can block most common-mode current from crossing from one side to another side of a transformer. Reduction of common-mode current crossing the transformer results in reduction of dipole radiation, which is the main component of electromagnetic interference (EMI) in some transformers.

An electrical component includes an insulating base, an insulating layer provided outside the insulating base, a shielding member provided between the insulating base and the insulating layer, and multiple conductive bodies accommodated in the insulating base. The conductive bodies include at least one power supply body. Each of the at least one power supply body is provided with a shielding layer outside the power supply body and an insulator between the power supply body and the shielding layer. The shielding layer is accommodated in the shielding member. In the electrical component, by providing a shielding layer and an insulator provided between the power supply body and the shielding layer outside the power supply body, shielding of the shielding layer from the power supply body is implemented, so as to reduce an interference of the power supply body on a signal body, thereby improving transmission quality of high-frequency signals.

A protection circuit module includes an insulating substrate, a first surge withstand chip resistor mounted on a pair of first pads formed on one surface of the insulating substrate, a second surge withstand chip resistor mounted on a pair of second pads formed on the other surface of the insulating substrate, and arranged at a position on the other surface of the insulating substrate overlapping the first surge withstand chip resistor in a plan view, a first wiring coupled to one first pad, a second wiring coupled to one second pad, a third wiring coupling the other first pad and the other second pad to the same potential, and a shield wiring provided on an inner layer of the insulating substrate and arranged in a region in which at least the one first pad and the one second pad oppose each other.

A wireless power receiver for wirelessly receiving power from a wireless power transmitter comprises: a power reception circuit receiving electromagnetic waves emitted from the wireless power receiver so as to output power having an alternating current waveform; a rectifier for rectifying the power, having an AC waveform, outputted from the power reception circuit into power having a direct current waveform; a DC/DC converter for converting, into a voltage of a preset level, a voltage of the power having a direct current waveform, the power being rectified by the rectifier; a charger for charging a battery by using the power having a DC waveform, converted from the DC/DC converter; an alternating current ground connected to the power reception circuit and/or the rectifier so as to receive at least a portion of the power having an alternating current waveform; and a direct current ground connected to the DC/DC converter and/or the charger so as to receive at least a portion of the power having a direct current waveform, wherein the alternating current ground and the direct current ground can be disposed on different PCB layers, respectively.

Embodiments herein relate to systems, apparatuses, processes or techniques directed to an impedance cushion coupled with a power plane to provide voltage for a system, where the impedance cushion is dimensioned to suppress resonance of the power plane to mitigate RFI or EMI emanating from the power plane during operation.

In a first region, a multilayer body is bent along a first bending line such that a first main surface is located farther on an outer peripheral side than a second main surface. In a second region, the multilayer body is bent along a second bending line such that the first main surface is located farther on an inner peripheral side than the second main surface. In the first region, a first metal foil layer is located farther on an outer peripheral side than a center of the multilayer body. In the second region, a second metal foil layer is located farther on the outer peripheral side than the center of the multilayer body. In the second region, a distance between the second metal foil layer and the second main surface is shorter than a distance between the second metal foil layer and the first main surface.

A method for manufacturing an interconnect structure is provided. The method includes the following steps. An opening is through a substrate. A low-k dielectric block is formed in the opening. At least one first via is formed through the low-k dielectric block. A first conductor is formed in the first via.

A printed circuit board includes a first insulating layer having a cavity, a metal pattern including a first shielding pattern disposed on an inner wall of the cavity and a second shielding pattern spaced apart from the first shielding pattern and covering the first shielding pattern, an electronic device positioned in the cavity and surrounded by the first shielding pattern and the second shielding pattern, and a second insulating layer stacked on the first insulating layer and embedding the electronic device therein.

A resin multilayer substrate includes a plurality of insulating resin base material layers and a plurality of conductor patterns provided on the plurality of insulating resin base material layers. The plurality of conductor patterns include a signal line and a ground conductor overlapping the signal line as viewed from a laminating direction of the insulating resin base material layers. A plurality of openings are provided in the ground conductor, and an aperture ratio is higher in a zone far from the signal line than in a zone adjacent to or in a vicinity of the signal line in a direction perpendicular or substantially perpendicular to the laminating direction.