A semiconductor assembly includes a first FET integrated within the semiconductor assembly and comprising gate, source and drain terminals. The semiconductor assembly further includes a low voltage switching device integrated within the semiconductor assembly and being configured to electrically short a gate-source capacitance of the first FET responsive to a control signal.

A semiconductor device, includes a die pad that has a first main surface and a second main surface located on the opposite side of the first main surface; a lead arranged next to the die pad; a semiconductor chip that has a surface, a first electrode and a second electrode formed on the surface, and a reverse side located on the opposite side of the surface, and is mounted on a chip mounting area of the first main of the die pad; a first wire that electrically couples the first electrode of the semiconductor chip and the lead; a second wire that electrically couples the second electrode of the semiconductor chip and the die pad; and a sealed body that seals the semiconductor chip, the first wire, and the second wire.

A multichip package and a method for manufacturing the same are provided. A multichip package includes: a plurality of semiconductor chips each mounted on corresponding lead frame pads; lead frames connected to the semiconductor chips by a bonding wire; and fixed frames integrally formed with at least one of the lead frame pads and configured to support the lead frame pads on a package-forming substrate.

A semiconductor module forming a semiconductor device includes lead frames in which switching elements are mounted on the side of upper surfaces and heat radiation surfaces are formed on the side of lower surfaces, and bus bars disposed on the lead frames and connecting between plural switching elements. The heat radiation surfaces of the lead frames are arranged on one plane and upper surfaces of flat surface portions of the bus bars are arranged on one plane, therefore, a layout property on the heat radiation surfaces or the upper surfaces the flat surface portions is good, which facilitates creation of a heat radiation structure and so on.

A device includes an integrated circuit (IC) die, a top-side base plate to which the IC die is mounted, and a body attached to the top-side base plate such that the IC die is inside the body, the body configured for attachment to a printed circuit board (PCB) such that the top-side base plate faces away from the PCB. The device may or may not include legs that abut the PCB upon installation.

The invention discloses a package structure for better heat-dissipation or EMI performance. A first conductive element and a second conductive element are both disposed between the top lead frame and the bottom lead frame. The first terminal of the first conductive element is electrically connected to the bottom lead frame, and the second terminal of the first conductive element is electrically connected to the top lead frame. The third terminal of the second conductive element is electrically connected to the bottom lead frame, and the fourth terminal of the second conductive element is electrically connected to the top lead frame. In one embodiment, a heat dissipation device is disposed on the top lead frame. In one embodiment, the molding compound is provided such that the outer leads of the top lead frame are exposed outside the molding compound.

A light emitting device includes a resin package and a light emitting element. The resin package has a cavity. The resin package includes first and second lead portions and a resin member. The first lead portion includes a first lead side surface and a lead recess portion that extends from the first lead side surface in a direction away from the second lead portion, with a part of the resin member being arranged within the lead recess portion. The light emitting element includes first and second electrodes that respectively face the first and second lead portions. The first electrode includes a first electrode side surface and an electrode recess portion that extends from the first electrode side surface in a direction away from the second electrode. The electrode recess portion is arranged at a position overlapping the lead recess portion in a plan view.

Two semiconductor elements and a capacitive element are located at vertices of a triangle. A first shortest path between the semiconductor elements, and a second shortest path and a third shortest path between the capacitive element and the two respective semiconductor elements, satisfy (first shortest path)≥(second shortest path) and ((first shortest path).sup.2+(second shortest path).sup.2)≥(third shortest path).sup.2. A first electrically conductive metal pattern and a second electrically conductive metal pattern each have a thickness that is equal to or larger than two times a depth of a skin through which current flows owing to skin effect generated according to frequency characteristics of current paths having: a first resonance frequency obtained from capacitances and inductances between the semiconductor elements; a second resonance frequency between one of the semiconductor elements and the capacitive element; and a third resonance frequency between another one of the semiconductor elements and the capacitive element.

In one example, a method of manufacturing a semiconductor device includes providing a substrate having substrate terminals and providing a component having a first component terminal and a second component terminal adjacent to a first major side of the component. The method includes providing a clip structure having a first clip, a second clip, and a clip connector coupling the first clip to the second clip. The method includes coupling the first clip to the first component terminal and a first substrate terminal and coupling the second clip to a second substrate terminal. The method includes encapsulating the component, portions of the substrate, and portions of the clip structure. the method includes removing a sacrificial portion of the clip connector while leaving a first portion of the clip connector attached to the first clip and leaving a second portion of the clip connector attached to the second clip. In some examples, the first portion of the clip connector includes a first portion surface, the second portion of the clip connector includes a second portion surface, and the first portion surface and the second portion surface are exposed from a top side of the encapsulant after the removing. Other examples and related structures are also disclosed herein.

An electronic package device and a carrier structure thereof are provided. The carrier structure includes a die attach paddle, a ground frame, a pin assembly, and a ground wing portion. The ground frame surrounds the die attach paddle. The pin assembly includes a plurality of pins that are spaced apart from one another. The pins extend radially outward and are arranged to surround the ground frame. The ground wing portion is connected to the ground frame and located in a space under the pin assembly. The ground wing portion includes an extending part and a joint part, the extending part extends away from the die attach paddle, and a top end of the extending part is located at a position above where a bottom surface of the die attach paddle is located.