An electronic device includes a multilevel lamination structure having a core layer, dielectric layers and conductive features formed in metal layers on or between respective ones or pairs of the dielectric layers. The core layer and the dielectric layers extend in respective planes of orthogonal first and second directions and are stacked along an orthogonal third direction. The conductive features include a first patterned conductive feature having multiple conductive turns in each of a first pair of the metal layers to form a first winding having a first turn and a final turn adjacent to one another in the same metal layer of the first pair, and a second patterned conductive feature having multiple conductive turns in a second pair of the metal layers to form a second winding having a first turn and a final turn.

There is provided a technique that includes: a lead having a main surface facing in a thickness direction; a semiconductor element mounted over the main surface; and a sealing resin that is in contact with the main surface and covers the semiconductor element, wherein the lead is formed with a plurality of grooves that are recessed from the main surface and are located apart from each other, and wherein the plurality of grooves are located away from a peripheral edge of the main surface.

A microelectronic device has a first die attached to a first die pad, and a second die attached to a second die pad. A magnetically permeable member is attached to a first coupler pad and a second coupler pad. A coupler component is attached to the magnetically permeable member. The first die pad, the second die pad, the first coupler pad, the second coupler pad, and the magnetically permeable member are electrically conductive. The first coupler pad is electrically isolated from the first die, from the second coupler pad, and from external leads of the microelectronic device. The second coupler pad is electrically isolated from the first die and from the external leads. The first die and the second die are electrically coupled to the coupler component. A package structure contains at least portions of the components of the microelectronic device and extends to the external leads.

A semiconductor package includes a first lead with first and second ends extending in the same direction as one another. At least one second lead has first and second ends and is partially surrounded by the first lead. A die pad is provided and a die is connected to the die pad. Wires electrically connect the die to the first lead and the at least one second lead. An insulating layer extends over the leads, the die pad, and the die such that the first end of the at least one second lead is exposed from the semiconductor package and the second end of the first lead is encapsulated entirely within the insulating layer.

An electronic device includes a die attach pad with a set of cantilevered first leads for down bond connections, a set of second leads spaced apart from the die attach pad, a semiconductor die mounted to the die attach pad and enclosed by a package structure, a set of first bond wires connected between respective bond pads of the semiconductor die and at least some of the first leads, and a set of second bond wires connected between respective further bond pads of the semiconductor die and at least some of the second leads.

Methods, systems, and apparatuses for a power card for use in a vehicle. The power card includes an N lead frame, a P lead frame, and an O lead frame each having a body portion and a terminal portion. The O lead frame is located between the N lead frame and the P lead frame. The power card includes a first power device located between the N lead frame and the O lead frame, with a first side coupled to the body portion of the N lead frame and a second side coupled to the body portion of the O lead frame. The power card includes a second power device located between the O lead frame and the P lead frame, with a first side coupled to the body portion of the O lead frame and a second side coupled to the body portion of the P lead frame.

In a described example, an apparatus includes: a package substrate including a die pad configured for mounting a semiconductor die, a first lead connected to the die pad, and a second lead and a third lead; and a semiconductor die including a temperature sensor mounted on the die pad. The semiconductor die includes a first metallization layer being a metallization layer closest to the active surface of the semiconductor die, and successive metallization layers overlying the previous metallization layer, the metallization layers including a respective conductor layer in a dielectric material for the particular metallization layer and conductive vias; and the temperature sensor formed of the conductor layer in an uppermost metallization layer and coupled to the second lead and to the third lead. The semiconductor die includes a high voltage ring formed in the uppermost metallization layer, spaced from and surrounding the temperature sensor.

An intelligent power module, which includes: a lead frame; a plurality of signal processing chips, disposed on the lead frame; at least one bridge die, configured to operably transmit signals among the signal processing chips; and a package structure, encapsulating the lead frame, the signal processing chips and the bridge die.

A semiconductor apparatus includes: a first semiconductor chip; a resin enclosure having a space in which the first semiconductor chip is positioned; a lead terminal disposed in the resin enclosure; a second semiconductor chip configured to: control the first semiconductor chip, and be disposed on a first portion of the resin enclosure, the resin enclosure not overlapping with the lead terminal, as seen in planar view from a direction perpendicular to a top surface of the lead terminal; and a wire having a first end connected to the lead terminal and a second end connected to the second semiconductor chip.

Provided is a semiconductor device including: a lead frame having an upper surface provided with a concave portion and a lower surface provided with a convex portion; a semiconductor chip fixed to the upper surface of the lead frame; a solder layer provided in the concave portion and fixing the semiconductor chip to the upper surface of the lead frame; and a sealing resin for sealing the semiconductor chip and the lead frame. A thickness of the solder layer is larger than a depth of the concave portion. The sealing resin covers at least a part of the lower surface of the lead frame. At least a part of the convex portion of the lead frame is exposed from the sealing resin.