A computing chip can include one or more voltage regulators to decrease a standard voltage, such as twelve volts, to a relatively low operating voltage of its processing cores, typically around one volt. Because the power consumed by the cores can be substantial, such as three hundred watts or more, it is desirable to locate the voltage regulators as close as possible to the cores, to reduce the distances that relatively large currents have to travel in the chip circuitry. The voltage regulators can be embedded within the package, such as in a layered structure, in a layer that electrically connects to the cores. While the cores are typically manufactured using the smallest possible lithographic features, the voltage regulators are less demanding and can instead use relatively large lithographic features, which can be formed using relatively old technology, and can therefore be relatively inexpensive.

A device that includes a substrate and a power amplifier coupled to the substrate. The substrate includes at least one dielectric layer, a plurality of interconnects, and a capacitor configured to operate as an output match element, where the capacitor is defined by a plurality of capacitor interconnects. The power amplifier is coupled to the capacitor. The capacitor is configured to operate as an output match element for the power amplifier. The substrate includes an inductor coupled to the capacitor, where the inductor is defined by at least one inductor interconnect. The capacitor and the inductor are configured to operate as a resonant trap or an output match element.

Techniques for fabricating a cored or coreless semiconductor package having one or more magnetic bilayer structures embedded therein are described. A magnetic bilayer structure includes a magnetic layer and a dielectric layer. For one technique, fabricating a cored or coreless semiconductor package includes: depositing a seed layer on a build-up layer; forming a raised pad structure and a trace on the seed layer; removing one or more uncovered portions of the seed layer to uncover top surfaces of one or more portions of the build-up layer; applying a magnetic bilayer structure on the raised pad structure, the trace, any unremoved portion of the seed layer, and the top surfaces of the one or more portions of the build-up layer, the magnetic bilayer structure comprises a magnetic layer and a dielectric layer; and forming a conductive structure on the raised pad structure. Other techniques are also described.

A power module includes at least one electrically conductive power substrate; and a plurality of power devices arranged on and connected to the at least one electrically conductive power substrate. The power module further includes at least one elevated signal element electrically connected to the plurality of power devices and/or at least one elevated power plane electrically connected to the at least one electrically conductive power substrate and electrically connected to the plurality of power devices.

A semiconductor die is disclosed, including circuitry comprising a transistor at a frontside of a semiconductor substrate, and a backside inductor at a backside of the semiconductor substrate. The backside inductor is electrically connected to the transistor of the circuitry.

An inductor structure, a package substrate, an integrated circuit device, an integrated circuit device assembly and a method of fabricating the inductor structure. The inductor structure includes: an electrically conductive body; and a magnetic structure including a non-electrically-conductive magnetic material, wherein: one of the magnetic structure or the electrically conductive body wraps around another one of the magnetic structure or the electrically conductive body to form the inductor structure therewith; and at least one of the electrically conductive body or the magnetic structure has a granular microstructure including randomly distributed particles presenting substantially non-linear particle-to-particle boundaries with one another.

In a described example, an apparatus includes a transformer including: an isolation dielectric layer with a first surface and a second surface opposite the first surface; a first inductor formed over the first surface, the first inductor comprising a first layer of ferrite material, and a first coil at least partially covered by the first layer of ferrite material; and a second inductor formed over the second surface, the second inductor comprising a second layer of ferrite material and a second coil at least partially covered by the second layer of ferrite material.

In one embodiment, an apparatus includes a first die with voltage regulator circuitry and a second die with logic circuitry. The apparatus further includes an inductor, a capacitor, and a conformal power delivery structure on the top side of the apparatus, where the voltage regulator circuitry is connected to the logic circuitry through the inductor, the capacitor, and the conformal power delivery structure. The conformal power delivery structure includes a first electrically conductive layer defining one or more recesses, a second electrically conductive layer at least partially within the recesses of the first electrically conductive layer and having a lower surface that generally conforms with the upper surface of the first electrically conductive layer, and a dielectric material between the surfaces of the first electrically conductive layer and the second electrically conductive layer that conform with one another.

A semiconductor device includes: a first semiconductor chip including a first coil that generates a magnetic field signal; a wiring board including a second coil, a third coil, and a twisted pair wiring, the second coil being disposed to face the first coil and receiving the magnetic field signal generated by the first coil, the twisted pair wiring connecting the second coil with the third coil; and a second semiconductor chip including a fourth coil disposed to face the third coil and receiving a magnetic field signal generated by the third coil.

The present technology relates to a semiconductor device and an electronic apparatus that make it possible to suppress the generation of noise in signals. A semiconductor device includes: a first semiconductor substrate on which at least a portion of a first conductor loop is formed; and a second semiconductor substrate on which a second conductor loop is formed. The second semiconductor substrate includes a first conductor layer and a second conductor layer. The first conductor layer and the second conductor layer each include a conductor. The first conductor layer and the second conductor layer are configured to cause a direction of a loop surface in which a magnetic flux is generated from the second conductor loop to be different from a direction of a loop surface in which an induced electromotive force is generated in the first conductor loop. The present technology is applicable, for example, to a CMOS image sensor.