Abstract: A device includes a leadframe having a diepad and leads, a compound semiconductor chip arranged over a first surface of the diepad and including gate, source electrode and drain electrodes, and an encapsulation material covering the compound semiconductor chip and diepad. A second surface of the diepad opposite the first surface is exposed from the encapsulation material. The device also includes a first lead of the leadframe electrically coupled to the gate electrode, a second lead of the leadframe electrically coupled to the source electrode, a third lead of the leadframe electrically coupled to the source electrode, and a fourth lead of the leadframe electrically coupled to the drain electrode. The third lead is configured to provide a sensing signal representing an electrical potential of the source electrode to a gate driver circuit. The gate driver circuit is configured to drive the gate electrode based on the sensing signal.

Abstract: A package encloses a power semiconductor die that has a first load terminal at a die frontside facing a footprint side of the package and a second load terminal arranged at a die backside facing a top side of the package. The package also includes a lead frame configured to electrically and mechanically couple the package to a support. The lead frame has a planar first outside terminal electrically connected with the first load terminal and a planar second outside terminal electrically connected with the second load terminal. The planar first outside terminal is configured to interface with the support by means of a first contact area. The planar second outside terminal is configured to interface with the support by means of a second contact area. The second contact area has a size in a range between 80% and 120% of a size of the first contact area.

Abstract: A package encloses a power semiconductor die and has a package body with a package top side, package footprint side and package sidewalls. The die has first and second load terminals for blocking a blocking voltage. A lead frame structure electrically and mechanically couples the package to a support and includes an outside terminal extending out of the package footprint side and/or the sidewalls, and is electrically connected with the first load terminal. A top layer arranged at the package top side is electrically connected with the second load terminal. A creepage length between the electrical potential of the outside terminal and the electrical potential of the top layer is defined by a package body surface contour. The surface contour is formed at least by the package top side and package sidewall. At least one structural feature also forms the surface contour is configured to increase the creepage length.

Abstract: A package encloses a power semiconductor die and has a package body with a top side, footprint side and sidewalls. The die has first and second load terminals and blocks a blocking voltage between the load terminals. The package further includes: a lead frame structure for electrically and mechanically coupling the package to a support, the lead frame structure including an outside terminal extending out of the package footprint side and/or out of one of the package sidewalls and electrically connected with the first load terminal; and a top layer arranged at the package top side and electrically connected with the second load terminal. A heat spreader is mounted onto the top layer with a bottom surface facing the top layer. The area of the top surface of the heat spreader is greater than the area of the bottom surface.

Abstract: In an embodiment, a semiconductor package includes a package footprint having a plurality of solderable contact pads, a semiconductor device having a first power electrode and a control electrode on a first surface and a second power electrode on a second surface, a redistribution substrate having an insulating board, wherein the first power electrode and the control electrode are mounted on a first major surface of the insulating board and the solderable contact pads of the package footprint are arranged on a second major surface of the insulating board, and a contact clip having a web portion and one or more peripheral rim portions. The web portion is mounted on and electrically coupled to the second power electrode and the peripheral rim portion is mounted on the first major surface of the insulating board.

Abstract: A method of making a semiconductor including soldering a conductor to an aluminum metallization is disclosed. In one example, the method includes substituting an aluminum oxide layer on the aluminum metallization by a substitute metal oxide layer or a substitute metal alloy oxide layer. Then, substitute metal oxides in the substitute metal oxide layer or the substitute metal alloy oxide layer are at least partly reduced. The conductor is soldered to the aluminum metallization using a solder material.

Abstract: A method of manufacturing a semiconductor device includes mounting a first semiconductor power chip on a first carrier, mounting a second semiconductor power chip on a second carrier, bonding a contact clip to the first semiconductor power chip and to the second semiconductor power chip, and mounting a third semiconductor chip over the contact clip.

Abstract: A package encloses a power semiconductor die and has a package body with a package top side, package footprint side and package sidewalls. The die has first and second load terminals and blocks a blocking voltage between the load terminals. The package further includes: a lead frame structure for electrically and mechanically coupling the package to a support, the lead frame structure including an outside terminal extending out of the package footprint side and/or out of one of the package sidewalls and electrically connected with the first load terminal; a top layer arranged at the package top side and electrically connected with the second load terminal; and a heat spreader arranged external of the package body and in electrical contact with the top layer. A top surface of the heat spreader has an area greater than the area of the bottom surface.

Abstract: A heat dissipation device includes a first part having a first material and a surface portion, and a second part on the surface portion. The second part has a second material and a porosity.

Abstract: A semiconductor package system comprises a semiconductor package and a cap. The semiconductor package comprises a die pad, a chip mounted or arranged to a first main face of the die pad and an encapsulation body encapsulating the chip and the die pad. The cap covers at least partly an exposed second main face of the die pad. The cap comprises a cap body of an electrically insulating and thermally conductive material and a fastening system fastening the cap to the semiconductor package. The fastening system extends from the cap body towards the encapsulation body or along a side surface of the semiconductor package.

Abstract: A power semiconductor arrangement includes a carrier and packages. Each package: encloses a power semiconductor die having first and second load terminals and configured to conduct a die load current between the load terminals; has a package body with a top side, a footprint side and sidewalls extending from the footprint side to the top side; a lead frame structure configured to electrically and mechanically couple the package to the carrier with the package footprint side facing the carrier, the lead frame structure including at least one first outside terminal electrically connected with the first load terminal of the die; a top layer arranged at the package top side and electrically connected with the second load terminal of the die. A top heatsink is attached to each package top layer, electrically contacted to each package top layer, and configured to conduct at least a sum of the die load currents.

Abstract: A device may include a carrier, a semiconductor chip arranged over a first surface of the carrier, and an encapsulation body comprising six side surfaces and encapsulating the semiconductor chip. A second surface of the carrier opposite to the first surface of the carrier is exposed from the encapsulation body. The device may further include electrical contact elements electrically coupled to the semiconductor chip and protruding out of the encapsulation body exclusively through two opposing side surfaces of the encapsulation body which have the smallest surface areas of all the side surfaces of the encapsulation body, and an electrically insulating layer arranged over the exposed second surface of the carrier.

Abstract: A semiconductor device includes a first lead frame, a second lead frame, a first semiconductor chip, and an encapsulation material. The first lead frame includes a first die pad having a first surface and a second surface opposite to the first surface. The second lead frame includes a second die pad having a first surface and a second surface opposite to the first surface. The first surface of the second die pad faces the first surface of the first die pad. The first semiconductor chip is attached to the first surface of the first die pad. The encapsulation material encapsulates the first semiconductor chip and portions of the first lead frame and the second lead frame. The encapsulation material has a first surface aligned with the second surface of the first die pad and a second surface aligned with the second surface of the second die pad.

Abstract: A method of manufacturing a semiconductor power package includes: embedding a power semiconductor chip in an encapsulation, the encapsulation forming a housing of the semiconductor power package; and extending a layer of a covering material over at least a part of an outer main surface of the encapsulation. The covering material has a thermal conductivity greater than a thermal conductivity of the material of the encapsulation and/or a temperature stability greater than a temperature stability of the pre-molded chip housing.

Abstract: In an embodiment, an electronic component includes a high-voltage depletion mode transistor including a current path coupled in series with a current path of a low-voltage enhancement mode transistor, a diode including an anode and a cathode, and a die pad. A rear surface of the high-voltage depletion mode transistor is mounted on and electrically coupled to the die pad. A first current electrode of the low-voltage enhancement mode transistor is mounted on and electrically coupled to the die pad. The anode of the diode is coupled to a control electrode of the high-voltage depletion mode transistor, and the cathode of the diode is mounted on the die pad.

Abstract: A method of manufacturing a semiconductor power package includes: providing a pre-molded chip housing and an electrically conducting chip carrier cast-in-place in the pre-molded chip housing; bonding a power semiconductor chip on the electrically conducting chip carrier; and applying a covering material so as to embed the power semiconductor chip. The covering material has an elastic modulus less than an elastic modulus of a material of the pre-molded chip housing and/or a thermal conductivity greater than a thermal conductivity of the material of the pre-molded chip housing and/or a temperature stability greater than a temperature stability of the pre-molded chip housing.

Abstract: A package encloses a power semiconductor die and has a package body with a package top side, package footprint side and package sidewalls. The die has first and second load terminals for blocking a blocking voltage. A lead frame structure electrically and mechanically couples the package to a support and includes an outside terminal extending out of the package footprint side and/or the sidewalls, and is electrically connected with the first load terminal. A top layer arranged at the package top side is electrically connected with the second load terminal. A creepage length between the electrical potential of the outside terminal and the electrical potential of the top layer is defined by a package body surface contour. The surface contour is formed at least by the package top side and package sidewall. At least one structural feature also forms the surface contour is configured to increase the creepage length.

Abstract: A package encloses a power semiconductor die and has a package body with a package top side, package footprint side and package sidewalls. The die has first and second load terminals and blocks a blocking voltage between the load terminals. The package further includes: a lead frame structure for electrically and mechanically coupling the package to a support, the lead frame structure including an outside terminal extending out of the package footprint side and/or out of one of the package sidewalls and electrically connected with the first load terminal; a top layer arranged at the package top side and electrically connected with the second load terminal; and a heat spreader arranged external of the package body and in electrical contact with the top layer. A top surface of the heat spreader has an area greater than the area of the bottom surface.

Abstract: An assembled semiconductor device and a method of making an assembled semiconductor device are disclosed. In one embodiment the assembled device includes a carrier having a first thickness, a connection layer disposed on the carrier and a chip disposed on the connection layer, the chip having a second thickness, wherein the second thickness is larger than the first thickness.

Abstract: A half bridge circuit includes an input connection configured to supply an electric input, an output connection configured to supply an electric output to a load to be connected to the output connection, a switch and a diode arranged between the input connection and the output connection and a voltage limiting inductance arranged in series between the switch and the diode. The voltage limiting inductance is configured to limit, upon switching the switch, a maximum voltage across the switch to below a breakdown voltage of the switch. A corresponding method of operating the half bridge circuit and package are also described.