A semiconductor device includes: a supporting member having a wiring including a die-pad; a semiconductor element bonded to the die-pad; a wire bonded to the wiring and the semiconductor element; and a bonding layer that has a conductivity and bonds the die-pad and the semiconductor element. When viewed in a thickness direction of the semiconductor element, the die-pad includes a first region included inside a peripheral edge of the semiconductor element and a second region that is connected to the first region and extends farther then the peripheral edge of the semiconductor element. When viewed in the thickness direction, the wire is separated from the second region.

A device includes a first conductive-member which connects to a first electrode on a first face of a chip. A second conductive-member is spaced from the chip and the first conductive-member. A third conductive-member is spaced from the first and second conductive-members. A first connector connects between the second electrode and the second conductive-member. A second connector is opposed to a third electrode on the second face and connects the third electrode and the third conductive-member. A first connecting-member connects the first connector and the second face. A second connecting-member connects the first connector and the second conductive-member. The first connector includes first protruded portions protruded in a first direction from the first conductive-member to the second conductive-member. The second connecting-member is provided to correspond to each of places between the first protruded portions and the second conductive-member.

In a general aspect, a power module includes a substrate having first, second and third patterned metal layers disposed on a surface of the substrate. The module also includes a first high-side transistor disposed on the first patterned metal layer, a second high-side transistor disposed on the first patterned metal layer, a first conductive clip electrically coupling the first high-side transistor with the second patterned metal layer, and a second conductive clip electrically coupling the second high-side transistor with the second patterned metal layer. The module further includes a first low-side transistor disposed on the second patterned metal layer, a second low-side transistor disposed on the second patterned metal layer, a third conductive clip electrically coupling the first low-side transistor with the third patterned metal layer, and a fourth conductive clip electrically coupling the second low-side transistor with the third patterned metal layer.

A method of forming one or more semiconductor packages includes mounting one or more semiconductor dies on the metal strip such that the one or more semiconductor dies are in a flip chip arrangement whereby terminals of the one or more semiconductor dies face the upper surface of the metal strip, forming an electrically insulating encapsulant material on the upper surface of the metal strip that encapsulates the one or more semiconductor dies, and forming package terminals that are electrically connected with the terminals of the one or more semiconductor dies, wherein the package terminals are formed from the metal strip or from metal that is deposited after removing the metal strip.

A semiconductor device has a substrate with a die mounting site and a plurality of leads. A first electrical component is disposed over a first surface of the die mounting site. A second electrical component is disposed over a second surface of the die mounting site opposite the first surface of the die mounting site. A first bond wire is coupled between the first electrical component and a first lead, and a second bond wire is coupled between the second electrical component and a second lead. A first encapsulant is deposited over the first electrical component, and a second encapsulant is deposited over the second electrical component with the leads exposed between the first encapsulant and second encapsulant. The leads are exposed from the first encapsulant and second encapsulant on a side of the semiconductor device.

In a semiconductor device, a first wiring member is electrically connected to a first main electrode on a first surface of a semiconductor element, and a second wiring member is electrically connected to a second main electrode on a second surface of the semiconductor element. An encapsulating body encapsulates at least a part of each of the first and second wiring members, the semiconductor element and a bonding wire. The semiconductor element has a protective film on the first surface of the semiconductor substrate, and the pad has an exposed surface exposed from an opening of the protective film. The exposed surface includes a connection area to which the bonding wire is connected, and a peripheral area on a periphery of the connection area. The peripheral area has a surface that defines an angle of 90 degrees or less relative to a surface of the connection area.

Aspects of the present disclosure include systems, structures, circuits, and methods providing voltage-isolated integrated circuit (IC) packages or modules having a transformer integrated with or implemented on a lead frame. A portion of transformer windings may include a conductive portion of a lead frame. Conductive structure, such as wire bonds, may be used for other portions of transformer windings. In some examples, an insulating coating may be placed on the package to increase the isolation capability of the final package. The IC packages and modules may include various types of circuits; in some examples, IC packages or modules may include a galvanically isolated gate driver or other high voltage circuit.

A semiconductor device includes a lead, a semiconductor substrate, a back-surface electrode provided between the semiconductor substrate and the lead, and a solder layer configured to connect the back-surface electrode and the lead. The back-surface electrode includes a silicide layer formed on a back surface of the semiconductor substrate, a bonding layer formed on the lead, a barrier layer formed on the bonding layer, and a stress relaxation layer formed between the silicide layer and the barrier layer. The stress relaxation layer is made of a first metal film containing aluminum as a main component or a second metal film containing gold, silver, or copper as a main component.

A power semiconductor module may comprise a common drain pad, a first power semiconductor device on a first region of the common drain pad, a second power semiconductor device on a second region of the common drain pad, a molding layer surrounding lateral parts of the first power semiconductor device and the second power semiconductor device on a peripheral region of the common drain pad, a common gate pad on the first power semiconductor device and the second power semiconductor device, and a source pad on the first power semiconductor device and the second power semiconductor device. The source pad may surround at least two outer lateral parts of the common gate pad.

The invention relates to a power semiconductor module comprising a conductive base, a conductive top, and at least two power semiconductor devices arranged between the conductive base and the conductive top. The semiconductor devices are each configured for a current of at least 1 A and/or for a voltage of at least 50 V. An insulating spacer layer is arranged on the power semiconductor devices and at least partially between the conductive base and the conductive top. At least two vertical connection elements pass from the power semiconductor devices through the spacer layer and conductively connect the conductive top with the power semiconductor devices. The spacer layer and the vertical connection elements are configured for compensating height differences of the power semiconductor devices.