2012 IEEE/MTT-S International Microwave Symposium Digest 2012
DOI: 10.1109/mwsym.2012.6258262
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A 2.6GHz band 537W peak power GaN HEMT asymmetric Doherty amplifier with 48% drain efficiency at 7dB

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Cited by 17 publications
(6 citation statements)
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“…Table I summarizes the measured amplifier performances and compares them with other state-of-the-art GaN FET amplifiers. These results are comparable to the best performance of the GaN on SiC FET high-power amplifiers [14]. As described above, our newly developed GaN FET on the LR Si substrate technology contributes to the coexistence of high performance and low cost in the high-power microwave GaN device.…”
Section: B 537-w Two-way Inverted Doherty Amplifiersupporting
confidence: 76%
“…Table I summarizes the measured amplifier performances and compares them with other state-of-the-art GaN FET amplifiers. These results are comparable to the best performance of the GaN on SiC FET high-power amplifiers [14]. As described above, our newly developed GaN FET on the LR Si substrate technology contributes to the coexistence of high performance and low cost in the high-power microwave GaN device.…”
Section: B 537-w Two-way Inverted Doherty Amplifiersupporting
confidence: 76%
“…While the Doherty architecture and its extensions (e.g., [5]- [7]) and envelope-tracking amplifier systems (e.g., [8], [9]) partially take advantage of saturated operation by utilizing saturation of the PA for a portion of the amplifier system or over a portion of the operating range, architectures that can leverage saturation (or switched-mode operation) over all or nearly all of the operating range have the potential for the highest efficiencies. Such architectures include polar amplifiers employing envelope elimination and restoration, or EER [10]- [12], amplifier systems utilizing direct load modulation of the power amplifier through electronic tuning [13]- [15], and outphasing amplifier systems [16]- [38].…”
Section: Introductionmentioning
confidence: 99%
“…1, if one further assumes that the PAs are outphased according the phasor relationship in Fig. 1 with all input-port voltages V A -V D having the same magnitude V S (at the combiner operating frequency), then one can solve (6) for the effective admittance Y eff,A -Y eff,D each of the PAs sees looking into the combiner as a function of the outphasing angles θ and φ with all other PAs active. As can be seen from (7), Y eff,A and Y eff,D , as well as Y eff,B and Y eff,C are complex conjugate pairs.…”
Section: A Input-port Admittance Characteristicsmentioning
confidence: 99%
“…In order to maintain high efficiency over a wide dynamic range, then, a promising approach is to exploit the saturated efficiency characteristic by continuing to operate in a saturated mode even as output power is modulated. Output power of a saturated PA can be controlled for example by modulating either the drain terminal, as in polar and envelope tracking techniques [1]- [3], modulation of the effective load impedance as in Doherty [4]- [6], outphasing [7]- [38], or direct load modulation [39]- [41] architectures, or through a combination of these approaches [42], [43]. In principle, the average modulated efficiency of these techniques is directly related to the extent to which saturated operation can be maintained.…”
Section: Introductionmentioning
confidence: 99%