Wideband Doherty amplifier

What is claimed is: 1. A wideband Doherty amplifier, comprising: Doherty amplifier circuitry comprising a main amplifier and a peaking amplifier; and a combining network having a first input coupled to an output of the main amplifier, a second input coupled to an output of the peaking amplifier, and an output, the combining network configured to combine a first amplified radio frequency signal from the output of the main amplifier and a second amplified radio frequency signal from the output of the peaking amplifier to provide a radio frequency output signal of the wideband Doherty amplifier; wherein the combining network comprises a wideband quarter-wave impedance transformer comprising: a quarter-wave impedance transformer; and compensation circuitry comprising two open stubs connected in parallel with the quarter-wave impedance transformer at a low-impedance end of the quarter-wave impedance transformer, the compensation circuitry configured to reduce a total quality factor of the wideband quarter-wave impedance transformer as compared to a quality factor of the quarter-wave impedance transformer. 2. The wideband Doherty amplifier of claim 1 wherein: the compensation circuitry has a quality factor that is at least approximately equal to the quality factor of the quarter-wave impedance transformer such that the total quality factor of the wideband quarter-wave impedance transformer is less than the quality factor of the quarter-wave impedance transformer. 3. The wideband Doherty amplifier of claim 1 wherein a total quality factor of the two open stubs is at least approximately equal to the quality factor of the quarter-wave impedance transformer such that the total quality factor of the wideband quarter-wave impedance transformer is less than the quality factor of the quarter-wave impedance transformer. 4. The wideband Doherty amplifier of claim 1 wherein the two open stubs are implemented by multi-layer transmission lines. 5. The wideband Doherty amplifier of claim 4 wherein a total quality factor of the two open stubs is at least approximately equal to the quality factor of the quarter-wave impedance transformer such that the total quality factor of the wideband quarter-wave impedance transformer is less than the quality factor of the quarter-wave impedance transformer. 6. The wideband Doherty amplifier of claim 1 wherein at least the combining network is implemented on a printed circuit board, and the two open stubs comprise: a first open stub comprising a first portion in a first metal layer of the printed circuit board and a second portion in a second metal layer of the printed circuit board, wherein the first and second portions are connected by one or more vias; and a second open stub comprising a first portion in the first metal layer of the printed circuit board and a second portion in the second metal layer of the printed circuit board, wherein the first and second portions of the second open stub are connected by one or more vias. 7. A wideband Doherty amplifier comprising: Doherty amplifier circuitry comprising a main amplifier and a peaking amplifier; and a combining network having a first input coupled to an output of the main amplifier, a second input coupled to an output of the peaking amplifier, and an output, the combining network configured to combine a first amplified radio frequency signal from the output of the main amplifier and a second amplified radio frequency signal from the output of the peaking amplifier to provide a radio frequency output signal of the wideband Doherty amplifier; wherein the combining network comprises a wideband quarter-wave impedance transformer comprising: a quarter-wave impedance transformer; and compensation circuitry comprising a half-wave transmission line connected in parallel to the quarter-wave impedance transformer at the low-impedance end of the quarter-wave impedance transformer such that: a first portion of the half-wave transmission line that extends from the quarter-wave impedance transformer to a first end of the half-wave transmission line forms a first open stub having a first length; and a second portion of the half-wave transmission line that extends from the quarter-wave impedance transformer to a second end of the half-wave transmission line forms a second open stub having a second length, the compensation circuitry configured to reduce a total quality factor of the wideband quarter-wave impedance transformer as compared to a quality factor of the quarter-wave impedance transformer. 8. The wideband Doherty amplifier of claim 7 wherein the first and second lengths are configured such that a quality factor of the first and second open stubs is at least approximately equal to the quality factor of the quarter-wave impedance transformer such that the total quality factor of the wideband quarter-wave impedance transformer is less than the quality factor of the quarter-wave impedance transformer. 9. The wideband Doherty amplifier of claim 7 wherein the half-wave transmission line is a micro strip. 10. The wideband Doherty amplifier of claim 7 wherein the half-wave transmission line is coaxial line. 11. The wideband Doherty amplifier of claim 7 wherein the half-wave transmission line is bent or meandered. 12. The wideband Doherty amplifier of claim 7 wherein the first and second lengths are optimized to maximize a bandwidth of the wideband quarter-wave impedance transformer. 13. A wideband Doherty amplifier comprising: Doherty amplifier circuitry comprising a main amplifier and a peaking amplifier; and a combining network having a first input coupled to an output of the main amplifier, a second input coupled to an output of the peaking amplifier, and an output, the combining network configured to combine a first amplified radio frequency signal from the output of the main amplifier and a second amplified radio frequency signal from the output of the peaking amplifier to provide a radio frequency output signal of the wideband Doherty amplifier; wherein the combining network comprises a wideband quarter-wave impedance transformer comprising: a quarter-wave impedance transformer; and compensation circuitry comprising a lumped element equivalent circuit for two open stubs connected in parallel to the quarter-wave impedance transformer at the low-impedance end of the quarter-wave impedance transformer having a quality factor that is at least approximately equal to the quality factor of the quarter-wave impedance transformer such that the total quality factor of the wideband quarter-wave impedance transformer is less than the quality factor of the quarter-wave impedance transformer. 14. The wideband Doherty amplifier of claim 1 wherein the quarter-wave impedance transformer has an input coupled to the output of the main amplifier and an output that corresponds to the low-impedance end of the quarter-wave impedance transformer. 15. The wideband Doherty amplifier of claim 14 wherein the combining network further comprises a second wideband quarter-wave impedance transformer comprising: a second quarter-wave impedance transformer having an input coupled to the output of the peaking amplifier and the output of the quarter-wave impedance transformer and an output that corresponds to a low-impedance end of the second quarter-wave impedance transformer; and second compensation circuitry connected in parallel with the second quarter-wave impedance transformer at the low-impedance end of the second quarter-wave impedance transformer, the second compensation circuitry configured to reduce a total quality factor of the second wideband quar