Design a Multi-Octave High-Efficiency Power Amplifier Using a Symmetrical Ring-Resonator Filtering Network With a Dual-Ring Embedded Architecture
Xuefei Xuan, Zhiqun Cheng, Brendan Hayes, Zhiwei Zhang, Chao Le, Tingwei Gong
Abstract
In this paper, a design strategy for a multi-octave high-efficiency power amplifier (PA) is presented by using a novel completely symmetric ring-resonator bandpass filtering network with a dual-ring embedded architecture. The presented strategy can achieve wideband frequency response and is relatively easy to analyze and implement due to the completely symmetrical structure employed. In addition, odd-even mode analysis and extended continuous Class-F mode are also used collaboratively to complete the bandwidth expansion and efficiency improvement of the PA. To verify the validity of the proposed design strategy, a prototype operating from 0.5 to 3.2 GHz ( fractional bandwidth of 146% ) is designed and implemented using a commercially available 10W GaN device. The fabricated PA achieves a measured drain efficiency ( DE ) of 60.8%-73.4% and gain of 9-12.1 dB at a saturated output power of 39-42.1 dBm over the whole operating bandwidth.