Abstract: Some features pertain to a device package that includes a die and a package substrate. The die includes a first switch. The package substrate is coupled to the die. The package substrate includes at least one dielectric layer, a primary inductor, and a first secondary inductor coupled to the first switch of the die. The first secondary inductor and the first switch are coupled to a plurality of interconnects configured to provide an electrical path for a reference ground signal. The primary inductor is configurable to have different inductances by opening and closing the first switch coupled to the first secondary inductor. In some implementations, the primary inductor is configurable in real time while the die is operational. In some implementations, the die further includes a second switch, and the package substrate further includes a second secondary inductor coupled to the second switch of the die.

Abstract: A matching technique and the field enhancement at the terminals of a bowtie nanoantenna is presented to develop compact, highly efficient, and flexible thermophotovoltaic (TPV) cells. The bowtie antenna is designed for maximum power transfer to a near infrared band of a TPV cell. In one example, a small cube of indium gallium arsenside antimode or another suitable material with a low bandgap energy of 0.52 eV is mounted at the terminals of the antenna. Such a load presents a frequency dependent impedance with a high resistance and capacitance at the desired frequency (180THz). For maximum power transfer, a high impedance bowtie antenna operating at the anti-resonance mode connected to an inductive transmission line to compensate for the load capacitance is realized. The same antenna and load configuration with the semiconductor material used in photoconductive mode is used to realize a sensitive uncooled photodetector.

Abstract: Some features pertain to a package substrate that includes at least one dielectric layer, an inductor in the at least one dielectric layer, a first terminal coupled to the inductor, a second terminal coupled to the inductor, and a third terminal coupled to the inductor. The first terminal is configured to be a first port for the inductor. The second terminal is configured to be a second port for the inductor. The third terminal is a dummy terminal. In some implementations, the package substrate includes a solder resist layer over the dielectric layer, where the solder resist layer covers the third terminal. In some implementations, the package substrate includes a solder interconnect over the third terminal, such that the solder resist layer is between the third terminal and the solder interconnect. In some implementations, the package substrate is coupled to a die comprising a plurality of switches.

Abstract: Low inductance to ground can be provided in wire-bond based device packages. An example device package may include a die on a package substrate, a mold on the package substrate and encapsulating the die, an upper ground conductor on the mold, and ground wire bonds within the mold. The die may include a plurality of terminals on an upper surface of the die. The plurality of ground wire bonds may electrically couple the die and the upper ground conductor. For each ground wire bond, a first end of that ground wire bond may be configured to electrically couple to a corresponding terminal on the upper surface of the die and a second end of that ground wire bond may be configured to electrically couple to the upper ground conductor at the upper surface of the mold.

Abstract: A flip-chip employing an integrated cavity filter is disclosed comprising an integrated circuit (IC) chip comprising a semiconductor die and a plurality of conductive bumps. The plurality of conductive bumps is interconnected to at least one metal layer of the semiconductor die to provide a conductive “fence” that defines an interior resonator cavity for providing an integrated cavity filter in the flip-chip. The interior resonator cavity is configured to receive an input RF signal from an input transmission line through an input signal transmission aperture provided in an internal layer in the semiconductor die. The interior resonator cavity resonates the input RF signal to generate the output RF signal comprising a filtered RF signal of the input RF signal, and couples the output RF signal on an output signal transmission line in the flip-chip through an output transmission aperture provided in the aperture layer.

Abstract: Some features pertain to a device package that includes a die and a package substrate. The die includes a first switch. The package substrate is coupled to the die. The package substrate includes at least one dielectric layer, a primary inductor, and a first secondary inductor coupled to the first switch of the die. The first secondary inductor and the first switch are coupled to a plurality of interconnects configured to provide an electrical path for a reference ground signal. The primary inductor is configurable to have different inductances by opening and closing the first switch coupled to the first secondary inductor. In some implementations, the primary inductor is configurable in real time while the die is operational. In some implementations, the die further includes a second switch, and the package substrate further includes a second secondary inductor coupled to the second switch of the die.

Abstract: Some features pertain to a package substrate that includes at least one dielectric layer, an inductor in the at least one dielectric layer, a first terminal coupled to the inductor, a second terminal coupled to the inductor, and a third terminal coupled to the inductor. The first terminal is configured to be a first port for the inductor. The second terminal is configured to be a second port for the inductor. The third terminal is a dummy terminal. In some implementations, the package substrate includes a solder resist layer over the dielectric layer, where the solder resist layer covers the third terminal. In some implementations, the package substrate includes a solder interconnect over the third terminal, such that the solder resist layer is between the third terminal and the solder interconnect. In some implementations, the package substrate is coupled to a die comprising a plurality of switches.

Abstract: A flip-chip employing an integrated cavity filter is disclosed comprising an integrated circuit (IC) chip comprising a semiconductor die and a plurality of conductive bumps. The plurality of conductive bumps is interconnected to at least one metal layer of the semiconductor die to provide a conductive “fence” that defines an interior resonator cavity for providing an integrated cavity filter in the flip-chip. The interior resonator cavity is configured to receive an input RF signal from an input transmission line through an input signal transmission aperture provided in an internal layer in the semiconductor die. The interior resonator cavity resonates the input RF signal to generate the output RF signal comprising a filtered RF signal of the input RF signal, and couples the output RF signal on an output signal transmission line in the flip-chip through an output transmission aperture provided in the aperture layer.

Abstract: An inductor structure includes a first set of traces corresponding to a first layer of an inductor, a second set of traces corresponding to a second layer of the inductor, and a third set of traces corresponding to a third layer of the inductor that is positioned between the first layer and the second layer. The first set of traces includes a first trace and a second trace that is parallel to the first trace. A dimension of the first trace is different from a corresponding dimension of the second trace. The second set of traces is coupled to the first set of traces. The second set of traces includes a third trace that is coupled to the first trace and to the second trace. The third set of traces is coupled to the first set of traces.

Abstract: An inductor structure includes a first set of traces corresponding to a first layer of an inductor, a second set of traces corresponding to a second layer of the inductor, and a third set of traces corresponding to a third layer of the inductor that is positioned between the first layer and the second layer. The first set of traces includes a first trace and a second trace that is parallel to the first trace. A dimension of the first trace is different from a corresponding dimension of the second trace. The second set of traces is coupled to the first set of traces. The second set of traces includes a third trace that is coupled to the first trace and to the second trace. The third set of traces is coupled to the first set of traces.

Abstract: A flip-chip employing an integrated cavity filter is disclosed comprising an integrated circuit (IC) chip comprising a semiconductor die and a plurality of conductive bumps. The plurality of conductive bumps is interconnected to at least one metal layer of the semiconductor die to provide a conductive “fence” that defines an interior resonator cavity for providing an integrated cavity filter in the flip-chip. The interior resonator cavity is configured to receive an input RF signal from an input transmission line through an input signal transmission aperture provided in an internal layer in the semiconductor die. The interior resonator cavity resonates the input RF signal to generate the output RF signal comprising a filtered RF signal of the input RF signal, and couples the output RF signal on an output signal transmission line in the flip-chip through an output transmission aperture provided in the aperture layer.

Abstract: A matching technique and the field enhancement at the terminals of a bowtie nanoantenna is presented to develop compact, highly efficient, and flexible thermophotovoltaic (TPV) cells. The bowtie antenna is designed for maximum power transfer to a near infrared band of a TPV cell. In one example, a small cube of indium gallium arsenside antimode or another suitable material with a low bandgap energy of 0.52 eV is mounted at the terminals of the antenna. Such a load presents a frequency dependent impedance with a high resistance and capacitance at the desired frequency (180 THz). For maximum power transfer, a high impedance bowtie antenna operating at the anti-resonance mode connected to an inductive transmission line to compensate for the load capacitance is realized. The same antenna and load configuration with the semiconductor material used in photoconductive mode is used to realize a sensitive uncooled photodetector.