Transformer-driven power switch devices are provided for switching high currents. These devices include power switches, such as Gallium Nitride (GaN) transistors. Transformers are used to transfer both control timing and power for controlling the power switches. These transformers may be careless, such that they may be integrated within a silicon die. Rectifiers, pulldown control circuitry, and related are preferably integrated in the same die as a power switch, e.g., in a GaN die, such that a transformer-driven switch device is entirely comprised on a silicon die and a GaN die, and does not necessarily require a (large) cored transformer, auxiliary power supplies, or level shifting circuitry.

An electronic package is provided, in which an electronic element is arranged on a carrier structure having a plurality of wire-bonding pads arranged on a surface of the carrier structure, and a plurality of bonding wires are connected to a plurality of electrode pads of the electronic element and the plurality of wire-bonding pads. Further, among any three adjacent ones of the plurality of wire-bonding pads, a long-distanced first wire-bonding pad, a middle-distanced second wire-bonding pad and a short-distanced third wire-bonding pad are defined according to their distances from the electronic element. Therefore, even if the bonding wires on the first to third wire-bonding pads are impacted by an adhesive where a wire sweep phenomenon occurred when the flowing adhesive of a packaging layer covers the electronic element and the bonding wires, the bonding wires still would not contact each other, thereby avoiding short circuit problems.

A bonding structure that may be used to form 3D-IC devices is formed using first oblong bonding pads on a first substrate and second oblong bonding pads one a second substrate. The first and second oblong bonding pads are laid crosswise, and the bond is formed. Viewed in a first cross-section, the first bonding pad is wider than the second bonding pad. Viewed in a second cross-section at a right angle to the first, the second bonding pad is wider than the first bonding pad. Making the bonding pads oblong and angling them relative to one another reduces variations in bonding area due to shifts in alignment between the first substrate and the second substrate. The oblong shape in a suitable orientation may also be used to reduce capacitive coupling between one of the bonding pads and nearby wires.

Semiconductor package structures are provided. A semiconductor package structure includes a chip, a molding material surrounding the chip, a through-via extending from a first surface to a second surface of the molding material, and a first re-distribution layer (RDL) wire disposed on the second surface of the molding material and electrically separated from the through-via. The second surface is opposite to the first surface. A portion of the first RDL wire across the through-via has a first segment with a first width and a second segment with a second width different from the first width.

A power semiconductor module including a positive-side switching device and a positive-side diode device which are mounted on a positive-side conductive pattern, and a negative-side switching device and a negative-side diode device which are mounted on an output-side conductive pattern. When an insulating substrate is viewed in plan view, the positive-side diode device and the negative-side diode device are disposed between the positive-side switching device and the negative-side switching device, and the negative-side diode device is disposed closer to the positive-side switching device than the positive-side diode device is.

Semiconductor package structures are provided. A semiconductor package structure includes a chip, a molding material surrounding the chip, a through-via extending from a first surface to a second surface of the molding material, and a first re-distribution layer (RDL) wire disposed on the second surface of the molding material and electrically separated from the through-via. The second surface is opposite to the first surface. A portion of the first RDL wire across the through-via has a first segment with a first width and a second segment with a second width different from the first width.

A power semiconductor module including a positive-side switching device and a positive-side diode device which are mounted on a positive-side conductive pattern, and a negative-side switching device and a negative-side diode device which are mounted on an output-side conductive pattern. When an insulating substrate is viewed in plan view, the positive-side diode device and the negative-side diode device are disposed between the positive-side switching device and the negative-side switching device, and the negative-side diode device is disposed closer to the positive-side switching device than the positive-side diode device is.

Semiconductor package structures are provided. A semiconductor package structure includes a chip, a molding material surrounding the chip, a through-via extending from a first surface to a second surface of the molding material, a first re-distribution layer (RDL) wire disposed on the second surface of the molding material and coupled to the through-via, and a second RDL wire disposed on the second surface of the molding material and parallel to the first RDL wire. The second surface is opposite to the first surface. A portion of the second RDL wire across the through-via has a first segment with a first width and a second segment with a second width different from the first width.

Semiconductor package structures are provided. A semiconductor package structure includes a chip, a molding material surrounding the chip, a through-via extending from a first surface to a second surface of the molding material, a first re-distribution layer (RDL) wire disposed on the second surface of the molding material and coupled to the through-via, and a second RDL wire disposed on the second surface of the molding material and parallel to the first RDL wire. The second surface is opposite to the first surface. A portion of the second RDL wire across the through-via has a first segment with a first width and a second segment with a second width different from the first width.

A semiconductor device with an anti-pad peeling structure is disclosed. The semiconductor device includes: a semiconductor substrate including a Through Substrate Via (TSV); a dielectric layer on the semiconductor substrate and including a plurality of recesses therein; and a pad above the semiconductor substrate to cover a portion of the dielectric layer and extend to the recesses; wherein the pad extends to the plurality of recesses, and a plurality of contact points are confined in the recesses between the pad and the conductive layer, and each of the contact points is at least partially excluded from a boundary of the TSV when being seen from a top-down perspective.