A package includes a first package and a second package over and bonded to the first package. The first package includes a first device die, and a first encapsulant encapsulating the first device die therein. The second package includes an Independent Passive Device (IPD) die, and a second encapsulant encapsulating the IPD die therein. The package further includes a power module over and bonded to the second package.

A semiconductor device includes a semiconductor substrate, a semiconductor layer, an insulating film, a conductive film, a first electrode pad, a second electrode pad, and a third electrode pad. The semiconductor layer includes a first semiconductor region having a first conductivity type and a second semiconductor region having a second conductivity type opposite to the first conductivity type. The insulating film is formed on the semiconductor layer. The conductive film is formed on the second semiconductor region through the insulating film interposed therebetween. The first electrode pad is configured to be electrically connected with the first semiconductor region and is configured to be electrically connected with the power supply circuit. The second electrode pad is configured to be electrically connected with the second semiconductor region and is configured to allow a signal to be provided toward an external circuit through the second electrode pad.

A structure includes a semiconductor substrate, a conductor-insulator-conductor capacitor. The conductor-insulator-conductor capacitor is disposed on the semiconductor substrate and includes a first conductor, a nitrogenous dielectric layer and a second conductor. The nitrogenous dielectric layer is disposed on the first conductor and the second conductor is disposed on the nitrogenous dielectric layer.

Systems and methods for providing 3D wafer assembly with known-good-dies are provided. An example method compiles an index of dies on a semiconductor wafer and removes the defective dies to provide a wafer with dies that are all operational. Defective dies on multiple wafers may be removed in parallel, and resulting wafers with all good dies stacked in 3D wafer assembly. In an implementation, the spaces left by removed defective dies may be filled at least in part with operational dies or with a fill material. Defective dies may be replaced either before or after wafer-to-wafer assembly to eliminate production of defective stacked devices, or the spaces may be left empty. A bottom device wafer may also have its defective dies removed or replaced, resulting in wafer-to-wafer assembly that provides 3D stacks with no defective dies.

Various embodiments of an integrated circuit package and a method of forming such package are disclosed. The package includes a substrate having a core layer disposed between a first dielectric layer and a second dielectric layer, a die disposed in a cavity of the core layer, and an encapsulant disposed in the cavity between the die and a sidewall of the cavity. The package further includes a first patterned conductive layer disposed within the first dielectric layer, a device disposed on an outer surface of the first dielectric layer such that the first patterned conductive layer is between the device and the core layer, a second patterned conductive layer disposed within the second dielectric layer, and a conductive pad disposed on an outer surface of the second dielectric layer such that the second patterned conductive layer is between the conductive pad and the core layer.

A component carrier has a stack including at least one electrically conductive layer structure and/or at least one electrically insulating layer structure. A component is embedded in the stack. The component includes a redistribution structure with at least one vertically protruding electrically conductive pad, and an electrically conductive material on at least part of said at least one pad. A method of manufacturing a component carrier is also disclosed.

A method for fabricating an electronic package is provided. A plurality of packaging structures are provided, each of which having a carrier and at least one electronic component disposed on the carrier. The plurality of packaging structures are disposed on a supporting plate. An encapsulation layer is formed on the supporting plate and encapsulates the plurality of packaging structures. Even if there are various types of electronic packages of different specifications in the market, the molds that the encapsulation layer uses can still be developed for a supporting plate of a certain specification. Therefore, the fabrication cost of the electronic package is reduced.

According to one configuration, an inductor device comprises: core material and one or more electrically conductive paths. The core material is magnetically permeable and surrounds (envelops) the one or more electrically conductive paths. Each of the electrically conductive paths extends through the core material of the inductor device from a first end of the inductor device to a second end of the inductor device. The magnetically permeable core material is operative to confine (guide, carry, convey, localize, etc.) respective magnetic flux generated from current flowing through a respective electrically conductive path. The core material stores the magnetic flux energy (i.e., first magnetic flux) generated from the current flowing through the first electrically conductive path. One configuration herein includes a power converter assembly comprising a stack of components including the inductor device as previously described as well as a first power interface, a second power interface, and one or more switches.

A radio frequency module includes: a module substrate including a principal surface; a bump electrode that is disposed on the principal surface and configured as an external-connection terminal of the radio frequency module; a semiconductor IC that is disposed on the principal surface and includes a low-noise amplifier that amplifies a radio frequency reception signal; an under-fill material disposed in a gap between the semiconductor IC and the principal surface; and a surface mount device disposed on the principal surface, between the bump electrode and the semiconductor IC, wherein in a plan view of the module substrate, an outer edge of the under-fill material is located between an edge of the inductor and an edge of the semiconductor IC, the respective edges of the inductor and semiconductor IC oppose the bump electrode.

Systems and methods for placing capacitors between IC bumps and BGA balls are described. In one embodiment, the method may include placing a ball grid array (BGA) package or integrated circuit (IC) package on a printed circuit board (PCB) of an electronic device, and placing a capacitor between a first BGA ball and a second BGA ball of the BGA package and/or placing a capacitor between a first IC bump and a second IC bump of the IC package to maintain impedance of a power delivery network (PDN) of the BGA package or IC package below a target impedance.