A semiconductor device includes: an MMIC having a DC pad; a bias substrate; a plurality of MIM capacitors mounted on the bias substrate; a plurality of pads provided on the bias substrate and respectively connected to overlying electrodes of the MIM capacitors; and a wire connecting the DC pad to any one of the plurality of pads, wherein the plurality of pads are arranged between the DC pad and the plurality of MIM capacitors in a planar view, and extend parallel to a row of the plurality of MIM capacitors laterally arranged side by side.

A transistor amplifier package includes a package substrate comprising conductive patterns exposed by solder mask patterns at a surface thereof, and at least one transistor die comprising a semiconductor structure attached to the surface of the package substrate by a solder material and aligned by the solder mask patterns such that respective gate, drain, and/or source terminals of the at least one transistor die are electrically connected to respective ones of the conductive patterns. Related transistor amplifiers and fabrication methods are also discussed.

Example embodiments relate to power amplifiers and Doherty amplifiers that include the same. One example embodiment includes a power amplifier. The power amplifier includes one or more radiofrequency (RF) output terminals. The power amplifier also includes a Gallium Nitride (GaN) semiconductor die on which a power field-effect transistor (FET) is integrated. The FET includes a plurality of FET cells that are adjacently arranged in a row. The FET cells are connected either directly or indirectly to the one or more RF output terminals via a respective first inductor. For FET cells arranged at opposing ends of the row of FET cells, a total FET cell gate width and an inductance of the first inductor is larger and smaller than the total FET cell gate width and inductance of the first inductor for one or more FET cells arranged in the middle of the row of FET cells, respectively.

A radio frequency (RF) chip package includes: an RF die; a first peripheral circuit chip; a second peripheral circuit chip; a substrate having a -shaped step formed on a portion thereof so that the RF die is mounted on top of the step of the substrate and the first peripheral circuit chip and the second peripheral circuit chip are mounted on top of the substrate where no step is formed; a first mutual inductance controller for controlling the dimension of the mutual inductance between the first peripheral circuit chip and the RF die; and a second mutual inductance controller for controlling the dimension of the mutual inductance between the second peripheral circuit chip and the RF die.

A possible benefit of the present disclosure is to further improve a heat dissipation property of an electronic component. A high-frequency module includes a mounting substrate, a filter (for example, a transmission filter), a resin layer, a shielding layer, and a metal member. The resin layer covers at least a portion of an outer peripheral surface (for example, an outer peripheral surface) of the filter. The shielding layer covers at least a portion of the resin layer. The metal member is disposed at a first principal surface of the mounting substrate. The metal member is connected to a surface of the filter on the opposite side from the mounting substrate, the shielding layer, and the first principal surface of the mounting substrate.

Aspects and embodiments disclosed herein include a stacked power amplifier cell comprising an active diffusion layer deposited on a substrate, a first series transistor including a first source electrode, a first drain electrode, and a first gate contact mounted on the active diffusion layer, and a second series transistor including a second source electrode, a second drain electrode, and a second gate contact mounted on the active diffusion layer, the second source electrode being electrically connected to the first drain electrode and a thickness of the second gate oxide layer being greater than a thickness of the first gate oxide layer.

The embodiments of the present disclosure provide a substrate device and a semiconductor package, the substrate device includes: first insulating layers and first functional layers stacked alternately, each of the first functional layers having a metal pattern, where the metal pattern includes an inductance coil, and the substrate device is adaptable for being positioned on a substrate.

An amplifier device may include at least one two-stage amplifier package, where an amplifier of a first amplification stage of the amplifier package may be aligned opposite to amplifiers of a second amplification stage of the amplifier package. The amplifier device may be a three-stage amplifier device, where the second stage of the two-stage amplifier package is coupled to amplifiers of a final (third) stage, which may be in a Doherty configuration. The amplifiers of the second stage may be arranged in any of a class AB configuration, a Doherty configuration, a multi-stage Doherty configuration (with amplifiers of the final amplification stage), or a multi-driver, multi-stage Doherty configuration. One or more passive components used for inter-stage impedance matching may be disposed outside of the two-stage amplifier package. Amplifiers of the first, second, and third amplification stages may each be gallium nitride (GaN) amplifiers, in some embodiments.

A method of fabricating a semiconductor device includes forming a protective structure on at least one die on a substrate. The protective structure exposes one or more electrical contacts on a first surface of the at least one die. Respective terminals are formed on the one or more electrical contacts exposed by the protective structure. Related packages and fabrication methods are also discussed.

Example embodiments relate to Doherty amplifiers. One example includes a radiofrequency (RF) power amplifier. The RF power amplifier includes an input lead. The RF power amplifier also includes a first output lead. Additionally, the RF power amplifier includes a first semiconductor die arranged in between the input lead and the first output lead. The first semiconductor die includes a first edge arranged adjacent to the input lead and an opposing second edge arranged adjacent to the first output lead. Further, the RF power amplifier includes a field-effect transistor integrated on the first semiconductor die. The field-effect transistor includes a gate bondpad assembly and a drain bondpad assembly. The field-effect transistor also includes a plurality of gate bondwires and a plurality of drain bondwires. In addition, the field-effect transistor includes a plurality of gate fingers extending in a first direction and a plurality of drain fingers extending in a second direction.