A radio frequency module has a substrate, a first chip inductor, an integrated circuit, and a first amplifier connected to the first chip inductor. The first chip inductor is on a first main surface of the substrate and the integrated circuit is on a second main surface of the substrate, the second main surface being opposite the first main surface. The integrated circuit includes the first amplifier. When the substrate is viewed from a direction perpendicular to the first main surface of the substrate, the first chip inductor at least partially overlaps the integrated circuit.

The present invention relates to a Doherty combiner used in a Doherty power amplifier, the Doherty combiner comprising: a phase shift section connected to one end of a carrier amplifier so as to change a phase of an RF signal output from the carrier amplifier; a matching section connected to an output terminal of the Doherty power amplifier so as to impedance-match an output of the Doherty power amplifier; and a bandwidth improvement section connected to one end of a peaking amplifier so as to change at least one of a phase bandwidth and an amplitude bandwidth of the Doherty power amplifier.

The present invention relates to a Doherty combiner used in a Doherty power amplifier, the Doherty combiner comprising: a phase shift section connected to one end of a carrier amplifier so as to change a phase of an RF signal output from the carrier amplifier; a matching section connected to an output terminal of the Doherty power amplifier so as to impedance-match an output of the Doherty power amplifier; and a bandwidth improvement section connected to one end of a peaking amplifier so as to change at least one of a phase bandwidth and an amplitude bandwidth of the Doherty power amplifier.

An amplifier circuit is a cascade amplifier circuit that includes a first transistor circuit including a signal input portion to which a signal is input from outside; a load circuit connected between the first transistor circuit and a power-supply line; and a second transistor cascode-connected between the load circuit and the first transistor circuit. The first transistor circuit is constituted by a plurality of transistors connected in parallel, and a bias circuit is provided that selectively supplies a bias voltage to the plurality of transistors.

An amplifier circuit is a cascade amplifier circuit that includes a first transistor circuit including a signal input portion to which a signal is input from outside; a load circuit connected between the first transistor circuit and a power-supply line; and a second transistor cascode-connected between the load circuit and the first transistor circuit. The first transistor circuit is constituted by a plurality of transistors connected in parallel, and a bias circuit is provided that selectively supplies a bias voltage to the plurality of transistors.

In an asymmetric Doherty amplifier circuit, one or more shunt reactive components are added to at least one side of an impedance inverter connecting the amplifier outputs, to reduce a capacitance imbalance between the two amplifiers caused by their different parasitic capacitances. This enables the (adjusted) parasitic capacitances to be incorporated into a quarter-wavelength transmission line, having a 90-degree phase shift, for the impedance inverter. In one embodiment, a shunt inductance is connected between the impedance inverter, on the side of the larger amplifier, and RF signal ground. The inductance is sized to resonate away substantially the excess parasitic capacitance of the larger amplifier. In another embodiment, a shunt capacitor is connected on the side of the smaller amplifier, thus raising its total capacitance to substantially equal the parasitic capacitance of the larger amplifier. In other embodiments shunt inductances and/or capacitors may be added to one or both amplifiers, and sized to effectively control a characteristic impedance of the impedance inverter.

A Doherty amplifier system is disclosed with a carrier amplifier configured to amplify a first portion of a radio frequency (RF) signal. A peaking amplifier with a peaking output is configured to amplify a second portion of the RF signal when it is above a power level threshold. A first inductor is coupled between the main output and a first middle node, and a second inductor is coupled between the first middle node and the peaking output. The first inductor and the second inductor are configured to have a first magnetic coupling to form a first impedance inverter. A third inductor is coupled between the peaking output and a second middle node, and a fourth inductor is coupled between the second middle node and an RF signal output. The third inductor and the fourth inductor are configured to have a second magnetic coupling to form a second impedance inverter.

A Doherty amplifier system is disclosed with a carrier amplifier configured to amplify a first portion of a radio frequency (RF) signal. A peaking amplifier with a peaking output is configured to amplify a second portion of the RF signal when it is above a power level threshold. A first inductor is coupled between the main output and a first middle node, and a second inductor is coupled between the first middle node and the peaking output. The first inductor and the second inductor are configured to have a first magnetic coupling to form a first impedance inverter. A third inductor is coupled between the peaking output and a second middle node, and a fourth inductor is coupled between the second middle node and an RF signal output. The third inductor and the fourth inductor are configured to have a second magnetic coupling to form a second impedance inverter.

A voltage controlled circuit includes a tracking circuit, an operational amplifier, a transistor, a feedback circuit and a sample and hold circuit. The tracking circuit generates an updated enabling voltage according to an enabling voltage, a sample enabling voltage and a sample reference voltage. The operational amplifier includes a first input terminal used to receive an input voltage, a second input terminal used to receive a feedback voltage, and an output terminal used to output a control voltage. The transistor includes a control terminal used to receive the control voltage, a first terminal used to receive a reference voltage, and a second terminal used to output a regulated voltage. The feedback circuit generates the feedback voltage according to the regulated voltage. The sample and hold circuit is used to sample the input voltage to generate the sample enabling voltage, and sample the feedback voltage to generate the sample reference voltage.

A cooling structure for a silicon-on-insulator (SOI) metal-oxide-semiconductor field-effect transistor (MOSFET) includes a plurality of semiconductor strips separated from each other by isolation trenches, each of the semiconductor strips extending away from a transistor P-well disposed on top of a buried oxide (BOX) layer formed in a semiconductor substrate and having first and second ends, the second end being farther than the first end from the transistor P-well. Applying a voltage to the plurality of semiconductor strips may generate, in at least one of the strips, a first area having a reduced temperature closer to the first end than to the second end of the strip and a second area having an increased temperature closer to the second end than to the first end of the strip. The first and second areas may be generated by the Peltier effect.