A semiconductor device includes an element region including a semiconductor substrate and a plurality of elements formed on the semiconductor substrate and a wiring region disposed on the element region and including an interlayer insulating layer, a plurality of wiring patterns in the interlayer insulating layer, and a via structure extending in a first direction, perpendicular to an upper surface of the semiconductor substrate in the interlayer insulating layer, wherein the plurality of elements include a first input/output circuit transmitting and receiving a first signal and a second I/O circuit transmitting and receiving a second signal, different from the first signal, the plurality of wiring patterns is a coil pattern includes an inductor circuit, the coil pattern is connected to the first I/O circuit, and the via structure passes through a center of the coil pattern and is connected to the second I/O circuit.

In conventional device packages, separate standalone inductors are provided and mounted on an interposer substrate along with a die. Separate inductors reduce integration density, decrease flexibility, increase footprint, and generally increase costs. To address such disadvantages, it is proposed to provide a part of an inductor in a substrate below a die. The proposed stacked substrate inductor may include a first inductor in a first substrate, a second inductor in a second a second substrate stacked on the first substrate, and an inductor interconnect coupling the first and second inductors. The core regions of the first and second inductors may overlap with each other at least partially. The proposed stacked substrate inductor may enhance integration density, increase flexibility, decrease footprint, and/or reduce costs.

In conventional device packages, separate standalone inductors are provided and mounted on an interposer substrate along with a die. Separate inductors reduce integration density, decrease flexibility, increase footprint, and generally increase costs. To address such disadvantages, it is proposed to provide a part of an inductor in a substrate below a die. The proposed stacked substrate inductor may include a first inductor in a first substrate, a second inductor in a second a second substrate stacked on the first substrate, and an inductor interconnect coupling the first and second inductors. The core regions of the first and second inductors may overlap with each other at least partially. The proposed stacked substrate inductor may enhance integration density, increase flexibility, decrease footprint, and/or reduce costs.

A semiconductor device includes an inductance structure and a shielding structure. The shielding structure is arranged to at least partially shield the inductance structure from external electromagnetic fields. The shielding structure includes a shielding structure portion arranged along a side of the inductance structure such that the shielding structure portion is around at least a portion of a perimeter of the inductance structure.

A stacked die power converter package includes a lead frame including a die pad and a plurality of package pins, a first die including a first power transistor switch (first power transistor) attached to the die pad, and a first metal clip attached to one side of the first die. The first metal clip is coupled to at least one package pin. A second die including a second power transistor switch (second power transistor) is attached to another side on the first metal clip. A controller is provided by a controller die attached to a non-conductive layer on the second metal clip on one side of the second die.

A stacked die power converter package includes a lead frame including a die pad and a plurality of package pins, a first die including a first power transistor switch (first power transistor) attached to the die pad, and a first metal clip attached to one side of the first die. The first metal clip is coupled to at least one package pin. A second die including a second power transistor switch (second power transistor) is attached to another side on the first metal clip. A controller is provided by a controller die attached to a non-conductive layer on the second metal clip on one side of the second die.

A semiconductor assembly with a package on package (POP) structure includes a first semiconductor package having a first lower substrate, a first upper substrate facing the first lower substrate, and a first semiconductor chip mounted on an area of the first lower substrate. The POP structure further includes a second semiconductor package having a second lower substrate stacked on the first semiconductor package and spaced apart from the first semiconductor package, and a second semiconductor chip mounted in an area of the second lower substrate. At least one passive element is disposed in one of the first upper substrate and the second lower substrate and electrically connected to the second semiconductor chip.

A power module (10) for operating an electric vehicle drive includes a current input configured for supplying an input current. The current input includes multiple contact elements (182, 184). Multiple circuit-breakers (142, 144) are configured for generating an output current based on the supplied input current. A current output (192) is configured for outputting the output current at a consumer. A substrate (12) includes a metal layer (122-130) and an insulating layer (121) connected to the metal layer (122-130). The multiple circuit-breakers (142, 144) are arranged on the metal layer (122-130). The multiple contact elements (182, 184) are also arranged on the metal layer (122-130) such that the multiple contact elements (182, 184) extend perpendicular to a surface of the substrate (12).

Some embodiments of the invention include a connecting structure between a support and at least one die attached to the support. The die includes a number of die bond pads on a surface of the die. The connecting structure includes a plurality of via and groove combinations. Conductive material is formed in the via and groove combinations to provide connection between the die bond pads and bond pads on the support. Other embodiments are described and claimed.

A radio frequency module includes: a module board that includes a first principal surface and a second principal surface on opposite sides of the module board; a power amplifier configured to amplify a transmission signal; a first circuit component; and a power amplifier (PA) control circuit configured to control the power amplifier. The power amplifier and the PA control circuit are stacked on the first principal surface, and the first circuit component is disposed on the second principal surface.