The present disclosure relates to an electronic device and a method of manufacturing a filtering component of the electronic device. The electronic device includes a semiconductor component, an insulating layer, at least one contact plug, and a filtering component. The insulating layer is disposed on the semiconductor component. The contact plug penetrates through the insulating layer. The filtering component is disposed on the insulating layer and the contact plug. The filtering component includes a bottom electrode, an isolation layer, a top electrode, and a dielectric layer. The bottom electrode is divided into a first segment connected to the contact plug and a second segment separated from the first segment. The isolation layer is disposed on the bottom electrode, the top electrode is disposed in the isolation layer, and the dielectric layer is disposed between the bottom electrode and the top electrode.

A semiconductor package includes a substrate. At least a high-frequency chip and a circuit component susceptible to high-frequency interference are disposed on a top surface of the substrate. A first ground ring is disposed on the substrate surrounding the high-frequency chip. A first metal-post reinforced glue wall is disposed on the first ground ring surrounding the high-frequency chip. A second ground ring is disposed on the top of the substrate surrounding the circuit component. A second metal-post reinforced glue wall is disposed on the second ground ring surrounding the circuit component. A molding compound covers at least the high-frequency chip and the circuit component. A conductive layer is disposed on the molding compound and is coupled to the first metal-post reinforced glue wall and/or the second metal-post reinforced glue wall.

The present disclosure provides a power module including a transformer, a first switching unit and a second switching unit; the transformer includes a magnetic core and a flatwise-wound winding wound around a winding pillar of the magnetic core; the flatwise-wound winding includes a first winding, a first end of the first winding and the first switching unit are electrically connected and are located on the first side face of the winding pillar, projections of the first switching unit, the first end of the first winding, and the winding pillar on the first side face overlap each other; a second end of the first winding and the second switching unit are electrically connected and are located on the second side face of the winding pillar, projections of the second switching unit, the second end of the first winding, and the winding pillar on the second side face overlap each other.

A receiver circuit includes a plurality of receivers, each of the receivers being associated with a carrier of a plurality of carriers, and a decoupler configured to receive a transmission signal from a transmission channel and output a plurality of divided transmission signals to the plurality of receivers. An equalizer is configured to modify either the transmission signal or one of the divided transmission signals.

Apparatus to form a transformer, an inductor, a capacitor or other passive electronic component, with patterned conductive features in a lamination structure, and one or more ferrite sheets or other magnetic core structures attached to the lamination structure via one or more inkjet printed magnetic adhesive layers that join the magnetic core structure or structures to the lamination structure.

Apparatus to form a transformer, an inductor, a capacitor or other passive electronic component, with patterned conductive features in a lamination structure, and one or more ferrite sheets or other magnetic core structures attached to the lamination structure via one or more inkjet printed magnetic adhesive layers that join the magnetic core structure or structures to the lamination structure.

A solar module (and its fabrication method) is presented where a supporting substrate comprises a network of finger traces connected to bus bars. Photo-active layer portions and upper electrode layer portions are deposited on the substrate thereby forming a network of cells. The cells are connected in series by connecting the bus bar of one cell to the upper electrode layer of the adjacent cell, and the bus bars of two adjacent cells are coupled through a bypass element for protecting the cell array.

A circuit system having compact decoupling structure, including: a mother board; at least one circuit unit, each having a substrate, a logic-circuit die, a plurality of first metal contacts, and a plurality of second metal contacts, the substrate having a first surface and a second surface, the first metal contacts being formed on the first surface and soldered onto the mother board, the second metal contacts being formed on the logic-circuit die and soldered onto the second surface to form flip-chip pillars, and the flip-chip pillars determining a height of a gap between the die and the substrate; and at least one decoupling unit for providing an AC signals decoupling function for the at least one circuit unit; wherein each of the at least one decoupling unit is placed in the gap of one said circuit unit and includes a mother die and at least one stack-type integrated-passive-device die.

Embodiments include semiconductor packages, such as wafer level chip scale packages (WLCSPs), flip chip chip scale packages (FCCSPs), and fan out packages. The WLCSP includes a first doped region on a second doped region, a dielectric on a redistribution layer, where the dielectric is between the redistribution layer and doped regions. The WLCSP also includes a shield over the doped regions, the dielectric, and the redistribution layer, where the shield includes a plurality of surfaces, and at least one of the plurality of surfaces of the shield is on a top surface of the first doped region. The WLCSP may have interconnects coupled to the second doped region and redistribution layer. The shield may be a conductive shield that is coupled to ground, and the shield may be directly coupled to the redistribution layer and first doped region. The first and second doped regions may include highly doped n-type materials.

Vertical capacitors for microelectronics are provided. An example thin capacitor layer can provide one or numerous capacitors to a semiconductor chip or integrated circuit. In an implementation, a thin capacitor layer of 50-100 m thickness may have 5000 vertically disposed capacitor plates per linear centimeter, while occupying only a thin slice of the package. Electrodes for each capacitor plate are accessible at multiple surfaces. Electrode density for very fine pitch interconnects can be in the range of 2-200 m separation between electrodes. A redistribution layer (RDL) may be fabricated on one or both sides of the thin capacitor layer to provide fan-out ball grid arrays that occupy insignificant space. RDLs or through-vias can connect together sets of the interior vertical capacitor plates within a given thin capacitor layer to form various capacitors from the plates to meet the needs of particular chips, dies, integrated circuits, and packages.