Example embodiments relate to lead frame based molded radio frequency packages. One example package includes a substrate. The package also includes a first electrical component arranged on the substrate. Additionally, the package includes a second electrical component. Further, the package includes a plurality of leads that are arranged spaced apart from the substrate and fixed in position relative thereto by a solidified molding compound. The leads were part of a lead frame prior to separating the package from the lead frame. The substrate was physically and electrically connected to the lead frame using a plurality of spaced apart connecting members prior to separating the package from the lead frame. During the separating of the package from the lead frame, each connecting member was divided into a first connecting member part and a second connecting member part. In addition, the package includes a frame part.

A Doherty amplifier includes a first amplifier that includes first output fingers and a first output electrode connected to the first output fingers, a second amplifier that includes second output fingers and a second output electrode connected to the second output fingers, a first bonding wire connected between a first region in the first output electrode and a second region in the second output electrode, a second bonding wire connected between a third region in the first output electrode and a fourth region in the second output electrode, and at least one of a first capacitor connected in series with the first bonding wire, and a second capacitor connected in parallel with the second bonding wire, wherein the first and the third regions are regions to which the first output fingers are connected, and the second and the fourth regions are regions to which second output fingers are connected.

An amplifier module that implements two or more amplifying units connected in series is disclosed. The amplifier module includes a package, input and output terminals, two or more amplifying units including the first unit and the final unit, an output bias terminal for supplying an output bias to one of amplifying units except for the final unit, and an input bias terminal for supplying an input bias to another one of the amplifying units except for the first unit. A feature of the amplifier module is that the output bias terminal and the input bias terminal are disposed in axial symmetry with respect to a reference axis connecting the input terminal with the output terminal in one side of the package.

A Doherty amplifier includes a peaking amplifier, a carrier amplifier, and a combining node electrically connected to the carrier amplifier and the peaking amplifier. The Doherty amplifier includes a harmonic control circuit coupled to the combining node. The harmonic control circuit includes an inductor and a capacitor and the inductor and capacitor are connected in series between the first current conducting terminal and a ground reference node. An inductance value of the inductor of the harmonic control circuit and a capacitance value of the capacitor of the harmonic control circuit are selected to terminate second order harmonic components of a fundamental frequency of a signal generated by the carrier amplifier.

A packaged RF transistor amplifier includes an RF transistor amplifier die having a first terminal, a first lead, an integrated passive device that includes a first series microstrip transmission line, a first bond wire coupled between the first terminal and the first series microstrip transmission line, and a second bond wire coupled between the first series microstrip transmission line and the first lead.

A multiple-path amplifier (e.g., a Doherty amplifier) includes first and second transistors (e.g., main and peaking transistors) with first and second output terminals, respectively, all of which is integrally-formed with a semiconductor die. A signal path through the second transistor extends in a direction from a control terminal of the second transistor to the second output terminal, where the second output terminal corresponds to or is closely electrically coupled to a combining node. The amplifier also includes an integrated phase delay circuit that is configured to apply an overall phase delay (e.g., 90 degrees) to a signal carried between the first and second output terminals. The integrated phase delay circuit includes delay circuit wirebonds coupled between the first and second output terminals, and the delay circuit wirebonds extend in a third direction that is angularly offset from (e.g., perpendicular to) the second direction.

The present disclosure relates to a transition system, which includes a monolithic microwave integrated circuit (MMIC) package and a printed-circuit-board (PCB) with a number of PCB vias. The MMIC package has a laminate-based body, which includes a substrate integrated waveguide (SIW) structure with a number of SIW vias, and a MMIC die over the laminate-based body. Herein, the SIW structure faces the PCB and is separate from the PCB with a gap in between. The SIW structure is configured to radiate radio frequency (RF) signals received from the MMIC die to the PCB. An arrangement of the PCB vias is scaling-mirrored to an arrangement of the SIW vias, such that each PCB via and a corresponding SIW via have a same relative position. The arrangement of PCB vias is about aligned with the arrangement of the SIW vias.

An amplifier includes a package that includes a carrier amplifier having a carrier amplifier input and output, a peaking amplifier having a peaking amplifier input and output, and corresponding input and output leads. The package includes a first integrated passive device including a first capacitor structure. The first integrated passive device includes a first contact pad coupled to the peaking amplifier output and a second contact pad coupled to the peaking output lead. The package includes a second integrated passive device including a second capacitor structure. The second integrated passive device includes a third contact pad coupled to the carrier amplifier output and a fourth contact pad coupled to the carrier output lead. The amplifier includes input circuitry a combining node configured to combine a carrier output signal and a peaking output signal.

A transistor device according to some embodiments includes a channel layer, a barrier layer on the channel layer, and source and drain contacts on the barrier layer, and a gate contact on the barrier layer between the source and drain contacts. The channel layer includes a sub-layer having an increased doping concentration level relative to a remaining portion of the channel layer. The presence of the sub-layer may reduce drain lag without substantially increasing gate lag.

The present invention includes a method for creating a system in a package with integrated lumped element devices and active devices on a single chip/substrate for heterogeneous integration system-on-chip (HiSoC) in photo-definable glass, comprising: masking a design layout comprising one or more electrical passive and active components on or in a photosensitive glass substrate; activating the photosensitive glass substrate, heating and cooling to make the crystalline material to form a glass-crystalline substrate; etching the glass-crystalline substrate; and depositing, growing, or selectively etching a seed layer on a surface of the glass-crystalline substrate on the surface of the photodefinable glass.