In a general aspect, an electronic device assembly can include a dielectric substrate having a first surface and a second surface opposite the first surface and a leadframe including a first leadframe portion including a first plurality of signal leads, and a second leadframe portion including a second plurality of signal leads. The substrate can be coupled with a subset of the first plurality of signal leads and a subset of the second plurality of signal leads. Signal leads of the first plurality, other than the subset of the first plurality of signal leads, can be spaced from the dielectric substrate. Signal leads of the second plurality, other than the subset of the second plurality of signal leads, can be spaced from the dielectric substrate. The assembly can further include one or more semiconductor die that are electrically coupled with the substrate and the leadframe portions.

In a general aspect, an apparatus can include an inner package including a first silicon carbide die having a die gate conductor coupled to a common gate conductor, and a second silicon carbide die having a die gate conductor coupled to the common gate conductor. The apparatus can include an outer package including a substrate coupled to the common gate conductor, and a clip coupled to the inner package and coupled to the substrate.

In some examples, a direct current (DC)-DC power converter package comprises a controller, a conductive member, and a first field effect transistor (FET) coupled to the controller and having a first source and a first drain, the first FET coupled to a first portion of the conductive member. The package also comprises a second FET coupled to the controller and having a second source and a second drain, the second FET coupled to a second portion of the conductive member, the first and second portions of the conductive member being non-overlapping in a horizontal plane. The first and second FETs are non-overlapping.

Example embodiments relate to lead frame based molded radio frequency packages. One example package includes a substrate. The package also includes a first electrical component arranged on the substrate. Additionally, the package includes a second electrical component. Further, the package includes a plurality of leads that are arranged spaced apart from the substrate and fixed in position relative thereto by a solidified molding compound. The leads were part of a lead frame prior to separating the package from the lead frame. The substrate was physically and electrically connected to the lead frame using a plurality of spaced apart connecting members prior to separating the package from the lead frame. During the separating of the package from the lead frame, each connecting member was divided into a first connecting member part and a second connecting member part. In addition, the package includes a frame part.

A power module is obtained in which the thermal resistance in the range from a semiconductor device to a base plate is reduced and the stress in the joining portion is relieved. The power module includes at least one semiconductor device, an insulating substrate having an insulating layer, a circuit layer provided on an upper surface of the insulating layer and a metal layer provided on a lower surface of the insulating layer, and a sintering joining member with an upper surface larger in outer circumference than a back surface of the at least one semiconductor device, to join together the back surface of the at least one semiconductor device and an upper surface of the circuit layer on an upper-surface side of the insulating layer.

Subject matter disclosed herein may relate to semiconductor devices, and may more particularly relate to power semiconductor packages, for example.

A semiconductor module includes a resin molded part encapsulating a semiconductor chip, a first terminal having a plate shape, and a second terminal having a plate shape. The first terminal and the second terminal are disposed on top of the other in a thickness direction. The first terminal is exposed from a first surface of the resin molded part, and the second terminal is projected from a second surface of the resin molded part to an outside of the resin molded part, the second surface being different from the first surface from which the first terminal is exposed.

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.

In a described example, an integrated circuit includes: a semiconductor substrate having a first surface and an opposite second surface; at least one dielectric layer overlying the first surface of the semiconductor substrate; at least one inductor coil in the at least one dielectric layer with a plurality of coil windings separated by coil spaces, the at least one inductor coil lying in a plane oriented in a first direction parallel to the first surface of the semiconductor substrate, the at least one inductor coil electrically isolated from the semiconductor substrate by a portion of the at least one dielectric layer; and trenches extending into the semiconductor substrate in a second direction at an angle with respect to the first direction, the trenches underlying the inductor coil and filled with dielectric replacement material.

This disclosure relates to a discrete cascode semiconductor device and associated method of manufacture, the device includes: a high voltage depletion mode device die having gate, source and drain terminals arranged on a first major surface thereof; a low voltage enhancement mode device die having a gate and a source terminal formed on a first major surface thereof, and a drain terminal formed on a second major surface opposite the first major surface. The drain terminal of the high voltage device die is mounted on a drain connection; the source terminal of the low voltage device die and the gate terminal of the high voltage device are mounted on a common source connection; and the drain terminal of the low voltage device die is mounted on the source terminal of the high voltage device.