An electronic component includes a substrate having a first main surface on one side and a second main surface on the other side, a chip having a first chip main surface on one side and a second chip main surface on the other side, and a plurality of electrodes formed on the first chip main surface and/or the second chip main surface, the chip being arranged on the first main surface of the substrate, a sealing insulation layer that seals the chip on the first main surface of the substrate such that the second main surface of the substrate is exposed, the sealing insulation layer having a sealing main surface that opposes the first main surface of the substrate, and a plurality of external terminals formed to penetrate through the sealing insulation layer so as to be exposed from the sealing main surface of the sealing insulation layer, the external terminals being respectively electrically connected to the plurality of electrodes of the chip.

A circuit device comprises a circuit board and a plurality of leads each comprising an island portion, a bonding portion elevated from the island portion, and an oblique slope portion connecting the island portion and the bonding portion, and a plurality of circuit elements mounted on the island portions so as to be connected to corresponding bonding portions through wirings. Two leads are adapted to be connected to positive and negative electrodes of a direct-current power source, and yet another lead is an output lead adapted to output alternating-current power. One electrode provided on a transistor mounted on an island portion of the second input lead is connected to a bonding portion of the output lead through a wiring, and another electrode provided on a transistor mounted on an island portion of the output lead is connected to a bonding portion of the first input lead through a wiring.

A chip package structure is provided. The chip package structure includes a first redistribution structure including a dielectric structure and wiring layers in the dielectric structure. The chip package structure includes a first chip over the first surface. The chip package structure includes a first conductive pillar over the first surface and electrically connected to the wiring layers. The chip package structure includes a second chip over the second surface. The second chip includes a second substrate and a second conductive pad over the second substrate, and the second conductive pad is between the second substrate and the first redistribution structure. The chip package structure includes a second conductive pillar over the second surface and electrically connected to the wiring layers.

A chip package structure is provided. The chip package structure includes a first redistribution structure including a dielectric structure and wiring layers in the dielectric structure. The chip package structure includes a first chip over the first surface. The chip package structure includes a first conductive pillar over the first surface and electrically connected to the wiring layers. The chip package structure includes a second chip over the second surface. The second chip includes a second substrate and a second conductive pad over the second substrate, and the second conductive pad is between the second substrate and the first redistribution structure. The chip package structure includes a second conductive pillar over the second surface and electrically connected to the wiring layers.

A semiconductor device, including a substrate having an insulating layer and a plurality of circuit patterns formed on the insulating layer, the substrate having a principal surface on which an element region is set. The semiconductor device further includes a plurality of semiconductor elements provided on the plurality of circuit patterns in the element region, a plurality of main terminals that each have a first end joined to one of the plurality of circuit patterns in the element region and a second end extending out of the substrate from a first side of the substrate, a plurality of control terminals disposed in a control region that is adjacent to a second side of the substrate opposite the first side, and a sealing member that seals the principal surface and the control region.

An embodiment method includes forming a first plurality of bond pads on a device substrate, depositing a spacer layer over and extending along sidewalls of the first plurality of bond pads, and etching the spacer layer to remove lateral portions of the spacer layer and form spacers on sidewalls of the first plurality of bond pads. The method further includes bonding a cap substrate including a second plurality of bond pads to the device substrate by bonding the first plurality of bond pads to the second plurality of bond pads.

An embodiment method includes forming a first plurality of bond pads on a device substrate, depositing a spacer layer over and extending along sidewalls of the first plurality of bond pads, and etching the spacer layer to remove lateral portions of the spacer layer and form spacers on sidewalls of the first plurality of bond pads. The method further includes bonding a cap substrate including a second plurality of bond pads to the device substrate by bonding the first plurality of bond pads to the second plurality of bond pads.

A semiconductor device includes an insulating substrate including an insulating plate and a circuit plate disposed on a main surface of the insulating plate; a semiconductor chip having a front surface provided with an electrode and a rear surface fixed to the circuit plate; a printed circuit board facing the insulating substrate and including a metal layer; a conductive post having one end electrically and mechanically connected to the electrode and another end electrically and mechanically connected to the metal layer; a passive element fixed to the printed circuit board; and a plurality of positioning posts fixed to the printed circuit board to position the passive element.

A power module includes: an insulating layer; a first metallic plate disposed on the insulating layer; a first semiconductor chip disposed on the first metallic plate; a first adhesive insulating layer and a second adhesive insulating layer disposed on the first metallic plate; a first metallic land for main electrode wiring disposed on the first adhesive insulating layer; and a first metallic land for signal wiring disposed on the second adhesive insulating layer. There can be provided a power module having reduced cost, reduced warpage of the whole of a substrate, stabilized quality, and improved reliability; and a fabrication method for such a power module.

An electronic component which comprises an electrically conductive carrier, an electronic chip on the carrier, an encapsulant encapsulating at least part of at least one of the carrier and the electronic chip, and a functional structure covering a surface portion of the encapsulant, wherein at least part of the covered surface portion of the encapsulant is spatially selectively roughened.