A semiconductor package assembly, comprising: a semiconductor package comprising: a semiconductor die mounted on a substrate; a pair of interconnection blocks mounted at opposite sides of the semiconductor die; and an encapsulant layer, wherein the pair of interconnection blocks have respective top surfaces exposed and a top surface of the semiconductor die is exposed; and an inductor block mounted on the semiconductor package, comprising: an inductor extending through the insulation body in a horizontal direction, and having a pair of inductor contact pads exposed at a bottom surface of the insulation body, wherein the pair of inductor contact pads are aligned to and electrically coupled to the pair of interconnection blocks; and a thermally conductive coating formed at an outer surface of the insulation body and extending in a vertical direction of the insulation body from the bottom surface to a top surface of the insulation body.

A power module includes a first end power semiconductor element and a second end power semiconductor element. A first sum is a sum of a path length between the gate electrode of the first end power semiconductor element and a first control terminal and a path length between the source electrode of the first end power semiconductor element and a first detection terminal. A second sum is a sum of a path length between the gate electrode of the second end power semiconductor element and the first control terminal and a path length between the source electrode of the second end power semiconductor element and the first detection terminal. The power module includes a first control layer connected to the gate electrode. The first control layer includes a first detour portion that detours the path to reduce a difference between the first sum and the second sum.

A switching module includes at least one substrate, at least one switching element, at least one control loop, a first power part and a second power part. The at least one switching element is disposed on the at least one substrate. The at least one control loop is connected with the corresponding switching element. The first power part is connected with the corresponding switching element. The second power part is connected with the corresponding switching element. A direction of a first current flowing through the first power part and a direction of a second current flowing through the second power part are identical. A projection of the first power part on a reference plane and a projection of the second power part on the reference plane are located at two opposite sides of a projection of the control loop on the reference plane.

A power module comprises: an upper arm structure that includes a first semiconductor switch, a second semiconductor switch and a first diode; a lower arm structure that includes a third semiconductor switch, a fourth semiconductor switch and a second diode; a first gate driving board, attached with the upper arm, wherein the first gate driving board includes a first gate driver connected to a first gate of the first semiconductor switch and a second gate driver connected to a second gate of the second semiconductor switch; a second gate driving board, attached with the lower arm, wherein the second gate driving board includes a third gate driver connected to a third gate of the third semiconductor switch and a fourth gate driver connected to a fourth gate of the fourth semiconductor switch; etc.

A switching component configured to switch an electrical signal, the switching component includes a substrate bearing several elementary components each ensuring the switching of the electrical signal, a baseplate onto which the substrate is fixed, the baseplate being configured to discharge heat emitted in the switchings of the switching component, two electrical conductors each connected to one of the elementary components and respectively ensuring the input and the output of the elementary component concerned for the signal (I.sub.C) to be switched, a magnetic core produced in a ferromagnetic material, the magnetic core surrounding the elementary component concerned without surrounding others of the elementary components and being disposed in the component in such a way that a displacement current between the surrounded elementary component and the baseplate induces a magnetic induction in the magnetic core, and in such a way that the path followed by a conduction current of the electrical signal switched by the component does not form a turn around the magnetic core.

Aspects of the present disclosure include systems, structures, circuits, and methods providing integrated circuit (IC) packages or modules having diagonalized leads. First and second semiconductor dies are disposed on a substrate. First and second coils are configured on the substrate for a transformer. The transformer may include a core. The leads or pins may be aligned along a diagonal of the package body, providing increased creepage. 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 packaged module includes an electrically conductive coil and a composite magnetic molding material covering the electrically conductive coil. The composite magnetic molding material includes a magnetic filler including coated magnetic particles (MB) dispersed in a composite non-magnetic material (MA). The composite magnetic molding material further includes a modulus reducing filler (MC) including modulus reducing particles or rubber particles or including functional groups having OH or COOH.

A packaged module including an electrically conductive coil mounted on a substrate. The packaged module is encapsulated with a magnetic molding compound covering the electrically conductive coil. The electrically conductive coil is core-less without a magnetic core disposed therein. The packaged module may further include an integrated circuit (IC) die disposed in the packaged module.

A packaged module including an electrically conductive coil disposed on a substrate and a magnetic molding compound encapsulating the packaged module. The magnetic molding compound includes coated magnetic metal particles dispersed in a non-magnetic material. The packaged module may be adapted to be used in a power management apparatus or a power conversion application system to increase an integration density and/or a power density of the system.

According to an embodiment of the present invention, a quantum processor includes a qubit chip. The qubit chip includes a substrate, and a plurality of qubits formed on a first surface of the substrate. The plurality of qubits are arranged in a pattern, wherein nearest-neighbor qubits in the pattern are connected. The quantum processor also includes a long-range connector configured to connect a first qubit of the plurality of qubits to a second qubit of the plurality of qubits, wherein the first and second qubits are separated by at least a third qubit in the pattern.