An integrated circuit includes a capacitor (e.g., a folded metal-oxide-metal (MOM) capacitor) formed in the lower BEOL interconnect levels, without degrading an inductor's Q-factor. The integrated circuit includes the capacitor in one or more back-end-of-line (BEOL) interconnect levels. The capacitor includes multiple folded capacitor fingers having multiple sides and a pair of manifolds on a same side of the folded capacitor fingers. Each of the pair of manifolds is coupled to one or more of the folded capacitor fingers. The integrated circuit also includes an inductive trace having one or more turns in one or more different BEOL interconnect levels. The inductive trace overlaps one or more portions of the capacitor.

A high-frequency module includes a multilayer substrate that includes an insulator layer and a wiring electrode, a component on one main surface of the multilayer substrate, a resin layer on the one main surface so as to cover the component, and a shield electrode covering at least a portion of a surface of the resin layer and at least a portion of a side surface of the multilayer substrate. The wiring electrode includes a capacitor via electrode that is spaced away from the shield electrode inside the multilayer substrate, and a first capacitor is defined by the shield electrode and the capacitor via electrode.

A filter unit according to the present invention includes a substrate, capacitors mounted on the substrate, and two inductors. The inductors each include a wire and a core. The core includes two core bodies. The core bodies each have a ring shape and include a wiring hole. The capacitors are disposed between the two core bodies. An opposed section extends from the respective two core bodies to a position opposed to the capacitors C. The opposed section is opposed to all of the plurality of capacitors.

Disclosed herein is a common mode filter that includes first and second terminal electrodes provided on the first flange part, third and fourth terminal electrodes provided on the second flange part, a first wire wound around the winding core part and having one end connected to the first terminal electrode and other end connected to the third terminal electrode, and a second wire wound around the winding core part and having one end connected to the second terminal electrode and other end connected to the fourth terminal electrode. The winding core part includes a first winding region, a second winding region, and a third winding region positioned between the first and second winding regions in the axial direction. The first and second wires are bifilar-wound in the first and second winding regions and layer-wound in the third winding region.

A packaged module for use in a wireless communication device has a substrate supporting an integrated circuit die that includes at least a microprocessor and radio frequency receiver circuitry and a stacked filter assembly configured as a filter circuit that is in communication with the radio frequency receiver circuitry. The stacked filter assembly includes a plurality of passive components, where each passive component is packaged as a surface mount device. At least one passive component is in direct communication with the substrate and at least another passive component is supported above the substrate by the at least one passive component that is in the direct communication with the substrate.

A packaged module for use in a wireless communication device has a substrate supporting a crystal assembly and a first die that implements at least a portion of a radio frequency baseband subsystem. The crystal assembly, positioned between the first die and the substrate, includes a crystal, an input terminal configured to receive a first signal, an output terminal configured to output a second signal, a conductive pillar, and an enclosure configured to enclose the crystal, where the conductive pillar is formed at least partially within a side of the enclosure and extends from a top surface to a bottom surface of the enclosure. The conductive pillar conducts a third signal distinct from the first and second signals.

A feedthrough subassembly for an active implantable medical device includes a metallic ferrule having a conductive ferrule body, at least one surface disposed on a device side, and a ferrule opening passing through the at least one surface. An insulator body hermetically seals the ferrule opening of the conductive ferrule body by at least one of a first gold braze ceramic seal, a glass seal or a glass-ceramic seal. At least one hermetically sealed conductive pathway is disposed through the insulator body. At least one pocket formed in the at least one surface has a gold pocket pad disposed within. When the first gold braze ceramic seal is present, the first gold braze ceramic seal and the gold pocket pad are not physically touching one another.

An electronic component includes a first inductor which is provided on a first direction side relative to a first main surface, which includes one or more first inductor conductive layers having substantially a spiral shape when viewed from the first direction side, and which includes a first end portion and a second end portion; a first outer electrode and a second outer electrode provided on a surface different from the first main surface of a substrate; and a first surface mounted electronic component which is provided on the first direction side relative to the first inductor, which overlaps the first inductor when viewed from the first direction side, and which includes a third outer electrode and a fourth outer electrode.

An electromagnetic wave shielding material is provided that is configured to prevent a usage environment from being limited. The electromagnetic wave shielding material shields an electromagnetic wave having a frequency, and includes a substrate and a plurality of resonance loops disposed on the substrate. Moreover, the plurality of resonance loops are positioned on the substrate to be magnetically coupled to each other. Each of the resonance loops forms an LC parallel resonance circuit that resonates at the frequency of the electromagnetic wave.

A wafer-level manufacturing method for embedding a passive element in a glass substrate is disclosed. A highly-doped silicon wafer is dry etched to form a highly-doped silicon mold wafer, containing highly-doped silicon passive component structures mold seated in cavity arrays; a glass wafer is anodically bonded to the highly-doped silicon mold wafer in vacuum pressure to seal the cavity arrays; the bonded wafers are heated so that the glass melts and fills gaps in the cavity arrays, annealing and cooling are performed, and a reflowed wafer is formed; the upper glass substrate of the reflowed wafer is grinded and polished to expose the highly-doped silicon passives; the passive component structure mold embedded in the glass substrate is fully etched; the blind holes formed in the glass substrates after the passive component structure mold has been etched is filled with copper by electroplating; the highly-doped silicon substrate and unetched silicon between the cavity arrays are etched, and several glass substrates embedded with a passive element are obtained; to form electrodes for the passives, a metal adhesion layer is deposited, and a metal conductive layer is electroplated. The process is simple, costs are low, and the prepared passive elements have superior performance.