The present disclosure is directed to a leadframe having a recess in a body of the leadframe to collect glue overflowing from the manufacturing process of coupling a semiconductor die to the leadframe. The recess extends beneath an edge of the semiconductor die so that any tendency of the glue to adhere to the semiconductor die is counteracted by a tendency of the glue to adhere to a wall of the recess and at least partially fill the volume of the recess. In addition, the recess for collecting adhesive may also form a mold lock on an edge of the leadframe, the mold lock providing a more durable connection between the leadframe and an encapsulant during physical and temperature stresses.

A semiconductor package comprises a lead frame, a chip, and a molding encapsulation. The lead frame comprises one or more die paddles comprising a first die paddle. The first die paddle comprises one or more through holes, one or more protrusions with grooves on top surfaces of the one or more protrusions, or one or more squeezed extensions. Each of the one or more through holes is filled with a respective portion of the molding encapsulation. Each of the one or more through holes may be of a rectangular shape, a rectangular shape with four filleted corners, a circular shape, or an oval shape. Each of the grooves is filled with a respective portion of the molding encapsulation. A respective side wall of each of the one or more squeezed extensions is of a swallowtail shape. The swallowtail shape directly contacts the molding encapsulation.

A multi-channel gate driver package includes a leadframe including a first, second, and third die pad. A transmitter die includes first and second transmitter signal bond pads, a first receiver die including a second signal bond pad, and a second receiver die including a third signal bond pad. A bond wire is between the first transmitter signal bond pad and the second signal bond pad, and between the second transmitter signal bond pad and third signal bond pad. A ring shield is around the respective signal bond pads. A downbond is from the second ring shield to the second die pad, and from the third ring shield to the third die pad. A connection connects the first and second transmitter ring shield to at least one ground pin of the package. The second and third die pad each include a direct integral connection to the ground pin.

A lead frame includes a support portion that has one end on which a first part and a second part that has a smaller thickness than the first part are arranged, a lead, and a heat sink that is welded to the support portion in the second part. A method of manufacturing the lead frame includes forming, from a metal plate, a frame member that includes a support portion and a lead, where the support portion has one end on which a first part and a second part that has a smaller thickness than the first part are arranged, and welding a heat sink to the support portion in the second part.

A semiconductor device includes a semiconductor package, including a package body that includes an encapsulant portion and an isolation structure, a semiconductor die embedded within the package body, and a plurality of leads that protrude out from the encapsulant body, wherein the encapsulant portion and the isolation structure are each electrically insulating structures, wherein the isolation structure has a greater thermal conductivity than the encapsulant portion, and wherein the isolation structure is thermally coupled to the semiconductor die, and a releasable layer affixed to the semiconductor package, wherein a first outer face of the package body includes a first surface of the isolation structure, wherein the releasable layer at least partially covers the first surface of the isolation structure, and wherein the releasable layer is releasable from the semiconductor package.

A lead-frame assembly is disclosed, for a semiconductor die and comprising a die attach pad and a plurality of elongate leads spaced apart therefrom; wherein each elongate lead has a first proximal end portion, a second distal end portion and a middle portion therebetween; wherein the die attach pad and each of the plurality of elongate leads each comprise a coating-free portion, and a coated portion having a coating material thereon; wherein a part of a perimeter of the die attach pad proximal each lead is comprised in the coating-free portion, and wherein the proximal end portion of each elongate lead is comprised in the coating-free portion. Associated package assemblies and methods are also disclosed.

A power semiconductor module includes: an electrically insulative frame having opposite first and second mounting sides, and a border that defines a periphery of the electrically insulative frame; a first substrate seated in the electrically insulative frame; a plurality of power semiconductor dies attached to the first substrate; a plurality of signal pins attached to the first substrate and electrically connected to the power semiconductor dies; a plurality of busbars attached to the first substrate and extending through the border of the electrically insulative frame; a plurality of fixing positions at the first mounting side of the electrically insulative frame; and a plurality of electrically insulative protrusions jutting out from the second mounting side of the electrically insulative frame, wherein the protrusions are vertically aligned with the fixing positions. Methods of producing the power semiconductor module and power electronic assemblies that incorporate the power semiconductor module are also described.

A 3-D package structure for isolated power module is discussed. The package structure has metal trace in a support layer (e.g. a substrate board), which is covered by two magnetic films from both sides, thus an effective transformer is formed. An IC die which contains a voltage regulator is stacked above the support layer, which significantly reduces the package size.

This disclosure relates to a cascode HEMT semiconductor device including a lead frame, a die pad attached to the lead frame, and a HEMT die attached to the die pad. The HEMT die includes a HEMT source and a HEMT drain on a first side, and a HEMT gate on a second side. The device further includes a MOSFET die attached to the source of the HEMT die, and the MOSFET die includes a MOSFET source, a MOSFET gate and a MOSFET drain. The MOSFET drain is connected to the HEMT source, and the MOSFET source includes a MOSFET source clip. The MOSFET source clip includes a pillar so to connect the MOSFET source to the HEMT gate, and the connection between the MOSFET source to the HEMT gate is established by a conductive material.

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.