An apparatus and method for a frequency based integrated circuit that selectively filters out unwanted bands or regions of interfering frequencies utilizing one or more tunable notch or bandpass filters or tunable low or high pass filters capable of operating across multiple frequencies and multiple bands in noisy RF environments. The tunable filters are fabricated within the same integrated circuit package as the associated frequency based circuitry, thus minimizing R, L, and C parasitic values, and also allowing residual and other parasitic impedance in the associated circuitry and IC package to be absorbed and compensated.

The present disclosure relates to a semiconductor package and a method of manufacturing the same. In some embodiments, a semiconductor package includes a substrate, at least one die, a sealing ring and an inductor. The at least one die is mounted on the substrate and includes a plurality of component structures operating with acoustic waves. The component structures are arranged on a side of the at least one die that faces the substrate. The sealing ring is disposed between the at least one die and the substrate and surrounds the component structures. The inductor is disposed in the substrate.

A Q-enhanced radio-frequency filter featuring loss-compensating circuits with values that can be controlled to optimize loss compensation. Instabilities are avoided by temporarily introducing a reflection at a port (such as via short-circuiting the port) and testing for the beginning of oscillations. Certain embodiments provide negative-resistance circuits for loss compensation, including cross-coupled transistor pairs and adjustable capacitance. Further embodiments provide loss-compensating RF filters with planar inductors, including overlapping planar inductors.

A package substrate is disclosed. The package substrate includes a die package in the package substrate located at least partially underneath a location of a power delivery interface in a die that is coupled to the surface of the package substrate. Connection terminals are accessible on a surface of the die package to provide connection to the die that is coupled to the surface of the package substrate. Metal-insulator-metal layers inside the die package are coupled to the connection terminals.

A semiconductor die and a transmission line structure has a first doped semiconductor substrate and a radio frequency transmission line disposed above the first doped semiconductor substrate. A second doped semiconductor segment is defined in the first doped semiconductor substrate and is arranged in a transverse relationship to a transmission line axis, with a depletion region being defined in areas of the first doped semiconductor substrate adjacent thereto that reduces power loss in signals through the transmission line.

A high peak bandwidth I/O channel embedded within a multilayer surface interface that forms the bus circuitry electrically interfacing the output or input port on a first semiconductor die with the input or output port on a second semiconductor die.

Embodiments of the invention include a microelectronic device that includes a transceiver coupled to a first substrate and a second substrate coupled to the first substrate. The second substrate includes an antenna unit for transmitting and receiving communications at a frequency of approximately 4 GHz or higher. An interposer substrate can provide a spacing between the first and second substrates.

RF amplifiers are provided that include a submount such as a thermally conductive flange. A dielectric substrate is mounted on an upper surface of the submount, the dielectric substrate having a first outer sidewall, a second outer sidewall that is opposite and substantially parallel to the first outer sidewall, and an interior opening. An RF amplifier die is mounted on the submount within the interior opening of the dielectric substrate, where a longitudinal axis of the RF amplifier die defines a first axis. The RF amplifier die is positioned so that a first angle defined by the intersection of the first axis with the first outer sidewall is between 5° and 45°. The dielectric substrate may be a ceramic substrate or a dielectric layer of a printed circuit board.

A package including a package substrate; an interposer electrically coupled to the package substrate and including a metal layer; a die including an integrated voltage regulator and electrically coupled to the interposer by solder features; and an inductor formed by a magnetic material disposed between two of the solder features electrically coupled to each other by a portion of the metal layer of the interposer, the inductor electrically coupled to the integrated voltage regulator.

A method includes placing an electronic device on a pliable mating surface on a major surface of a mold such that at least one contact pad on the electronic device presses against the pliable mating surface. The pliable mating surface is on a microstructure in an arrangement of microstructures on the major surface of the mold. A liquid encapsulant material is applied over the electronic device and the major surface of the mold, and then hardened to form a carrier for the electronic device. The mold and the carrier are separated such that the microstructures on the mold form a corresponding arrangement of microchannels in the carrier, and at least one contact pad on the electronic device is exposed in a microchannel in the arrangement of microchannels. A conductive particle-containing liquid is deposited in the microchannel, which directly contacts the contact pad exposed in the microchannel.