A semiconductor package comprises a leadframe with a first lead and a second lead where the first lead has a larger size compared to the second lead. The lead frame further comprises a die attach area on which a die with one or more bond pads of the die is attached and where the first lead and the second lead extend outwardly from the die attach area. The one or more bond pads are associated with the first lead and a plurality of bond wires is arranged between a bond pad and the first lead.

A lead frame according to the present embodiments includes: a main body portion having a main surface including a mounting region on which a semiconductor chip is to be mounted; a lead portion connected to the main body portion; a groove portion provided in a main surface of the main body portion so as to surround the mounting region, the groove portion having an inner side surface and an outer side surface; and a protruding portion protrudingly provided along an inner edge of the groove portion.

In one example, a semiconductor device includes a conductive structure having a conductive structure upper side. A roughening is on the conductive structure upper side and a groove is in the conductive structure extending partially into the conductive structure from the conductive structure upper side. An electronic component is attached to the conductive structure upper side with an attachment film. An encapsulant covers the electronic component, at least portions of the roughening, and at least portions of the conductive structure upper side. The groove has smoothed sidewalls that include substantially planarized portions of the roughening. The smooth sidewalls reduce flow of the attachment film across the conductive structure upper side to improve adhesion of the encapsulant to the conductive structure. Other examples and related methods are also disclosed herein.

A semiconductor device comprising a terminal, a semiconductor element and a sealing resin. The semiconductor element is disposed on one side of the terminal in a first direction and electrically connected to the terminal. The sealing resin covers the semiconductor element and a part of the terminal. The sealing resin has a bottom surface disposed on an opposite side to the semiconductor element with respect to the terminal in the first direction. The terminal extends beyond the bottom surface.

An electronics assembly includes a plurality of planar conductive metal sheets including a first conductive metal sheet, a second conductive metal sheet attached and electrically coupled to the first metal sheet, and a third conductive metal sheet attached and electrically coupled to the second metal sheet. The second metal sheet is located between the first and third conductive metal sheets. Air gaps are defined in the plurality of planar conductive metal sheets to form metal traces that define electrically isolated conductive paths from an outer surface of the first conductive metal sheet to an outer surface of the third conductive metal sheet in a multilevel conductive wiring network. The multilevel conductive wiring network can be attached and electrically coupled to a microchip and to one or more capacitors to form a power converter.

An example packaged IC includes a lead frame having a supply pin and a ground pin. The supply pin includes first and second supply leads extending from a proximal portion of the supply pin. The ground pin includes first and second ground leads extending from a proximal portion of the ground pin. A first IC network has a first supply terminal coupled to the first supply lead via a first conductor (e.g., bond wire or bump bond). The first IC network also has a first ground terminal coupled to the first ground lead via a second conductor. A second IC network has a second supply terminal coupled to the second supply lead via a third conductor. The second IC network also has a second ground terminal coupled to the second ground lead via a fourth conductor.

A molded package includes: a semiconductor die; a substrate attached to a bottom side of the semiconductor die; an electrically conductive clip attached to a top side of the semiconductor die; and a mold compound encapsulating the semiconductor die. A top side of the electrically conductive clip faces away from the semiconductor die and has an exposed flat surface that overlays the semiconductor die and is not covered by the mold compound. A bottom side of the electrically conductive clip faces the semiconductor die and has a convex curved surface that is attached to the top side of the semiconductor die. Along a vertical cross-section of the electrically conductive clip from the exposed flat surface to the convex curved surface, the electrically conductive clip has a plano-convex shape delimited by the exposed flat surface and the convex curved surface. A method of producing the molded package is also described.

Even if there is a change in the shape of a transfer mold power module is required, a change in a position of the electrode of the module is facilitated by separating electrode terminals of a power module from the electrodes and retrofitting the separated electrode terminals to the electrodes with high precision. A semiconductor device includes a mold resin enclosing a semiconductor chip, an electrode electrically connected to the semiconductor chip and exposed in an opening provided in the mold resin, and an electrode terminal having a contact portion that covers the electrode and is in electrical contact with the electrode, a plurality of projections formed to surround the contact portion and provided between a side surface of the opening and the contact portion, a contact end portion having the contact portion and an open end portion which is a different end portion from the contact end portion.

In one example, an electronic device, comprises a substrate comprising a first side and a second side opposite to the first side, wherein the substrate comprises dimples on the first side of the substrate, an electronic component over the first side of the substrate, an encapsulant over the first side of the substrate and covering a lateral side of the electronic component, and a first interconnect in the encapsulant and coupled to the electronic component and the substrate. Other examples and related methods are also disclosed herein.

The present disclosure is directed to semiconductor packages manufactured utilizing a leadframe with varying thicknesses. The leadframe with varying thicknesses has a reduced likelihood of deformation while being handled during the manufacturing of the semiconductor packages as well as when being handled during a shipping process. The method of manufacturing is not required to utilize a leadframe tape based on the leadframe with varying thicknesses. This reduces the overall manufacturing costs of the semiconductor packages due to the reduced materials and steps in manufacturing the semiconductor packages as compared to a method that utilizes a leadframe tape to support a leadframe. The semiconductor packages may include leads of varying thicknesses formed by utilizing the leadframe of varying thicknesses to manufacture the semiconductor packages.