A sand blasting fixture is used to allow a half-etched elongated slit of a lead frame to be processed a sandblasting operation, and includes a lower mold, an upper mold and a positioning component. The lower mold includes a lower cover plate. The upper mold includes an upper cover plate and a sandblasting elongated hole. The upper cover plate is removably covered by the lower cover plate, the sandblasting elongated hole is penetrated through the upper cover plate, and featured with the same appearance with the half-etched elongated slit. The positioning component is connected to the upper cover plate for fixing the lead frame on the upper cover plate so that the upper cover plate is allowed to completely cover one surface of the lead frame and the half-etched elongated slit is completely overlapped and exposes from the sandblasting elongated hole of the upper cover plate.

In a described example, an apparatus includes: a metal leadframe including a dielectric die support formed in a central portion of the leadframe, and having metal leads extending from the central portion, portions of the metal leads extending into the central portion contacted by the dielectric die support; die attach material over the dielectric die support; a semiconductor die mounted to the dielectric die support by the die attach material, the semiconductor die having bond pads on a device side surface facing away from the dielectric die support; electrical connections extending from the bond pads to metal leads of the leadframe; and mold compound covering the semiconductor die, the electrical connections, the dielectric die support, and portions of the metal leads, the mold compound forming a package body.

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 semiconductor device includes a package body having a topside in a first plane and a bottom side in a second plane parallel to the first plane. At least one lead protruding out of the package body has a first portion in a plane parallel to the first plane and a second portion being bent away from the first plane towards the second plane. A cavity is positioned between the at least one lead and a feature of the semiconductor device. A removable dielectric spacer is configured to be positioned in the cavity between the at least one lead and the feature. The dielectric spacer is longer than the at least one lead.

A method of manufacturing a semiconductor device is provided. The method includes forming a package leadframe including a die pad, a first ridge formed at a first outer edge of the die pad, a second ridge formed at a second outer edge of the die pad opposite of the first outer edge and separate from the first ridge, and a plurality of leads surrounding the die pad. A semiconductor die is attached to the die pad by way of a die attach material. The semiconductor die is located on the die pad between the first ridge and the second ridge. An encapsulant encapsulates the semiconductor die and at least a portion of the package leadframe.

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.

An electronic package includes an electronic component including terminals, a plurality of surface contacts, at least some of the surface contacts being electrically coupled to the terminals within the electronic package, a mold compound covering the electronic component and partially covering the surface contacts with a bottom surface exposed from the mold compound, and a plurality of wires extending from exposed surfaces of the surface contacts, each of the wires providing a solderable surface for mounting the electronic package at a standoff on an external board.

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.

A package and method is disclosed. In one example, the package comprises a carrier comprising a component mounting area from which a tie bar extends, the tie bar being configured for being clamped by an encapsulation tool pin during encapsulation, an electronic component mounted on the component mounting area, and an encapsulant encapsulating at least part of the electronic component and at least part of the carrier, wherein a sidewall of the package has a step between a first vertical sidewall section and a second vertical sidewall section; wherein the first vertical sidewall section has a notch in the encapsulant and a part of the second vertical sidewall section exposes the tie bar.

A method of manufacturing a semiconductor device includes providing a conductive frame defining first and second rails, a first terminal disposed between the rails, and a plurality of second terminals extending toward the first terminal from one or both of the rails, disposing a plurality of unencapsulated stacks of capacitor(s) on the frame, each of the stacks having electrically isolated first and second contacts and being disposed with the first contact electrically connected to the first terminal and the second contact electrically connected to one of the second terminals, encapsulating the plurality of stacks, and removing the rails from the frame. The method may include electrically connecting the first terminal to a ground line of the semiconductor device and electrically connecting each of the second terminals to a respective power rail of the semiconductor device associated with a respective voltage potential.