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Low-Noise Dual-Way Magnetron Power-Combining System Using an Asymmetric H-Plane Tee and Closed-Loop Phase Compensation

Xiaojie Chen, Bo Yang, Naoki Shinohara, Changjun Liu

2021IEEE Transactions on Microwave Theory and Techniques28 citationsDOI

Abstract

To meet the increasing power demands of microwave industries and scientific innovations, a dual-way magnetron (MGT) power-combining system based on an asymmetric H-plane tee combined with closed-loop phase compensation (CLPC) was developed and tested. Only one external injection was used, which could lock both frequencies of the two MGTs via the port coupling of the asymmetric H-plane tee. Additionally, phase control was achieved simultaneously in both MGTs. By tuning the external frequency, the frequencies of both MGTs could be shifted to optimize the power-combining efficiency. The optimal combining efficiency was 95.7%. By adjusting the phase of the external injection, the phase for the combining output was adjusted with a control scope in the 0°-360° range. The phase noise level of the combined output was largely inhibited by implementing only one closed-loop phase compensation subsystem. The phase jitter was limited to approximately ±0.5°, and spur suppression ratios of -61.0 dBc/Hz at 10 Hz, -80.9 dBc/Hz at 100 Hz, -91.6 dBc/Hz at 1 kHz, and so on were achieved. Moreover, we deduced the corresponding power-combining theories in the asymmetric H-plane tee and noise reduction using the closed-loop compensation method. The numerical predictions qualitatively agreed with the experimental results. Additionally, this research reveals that the proposed techniques have great potential for future power-combining systems because they provide higher power output and noise reduction.

Topics & Concepts

dBcPhase noisePower (physics)Compensation (psychology)Control theory (sociology)Noise (video)JitterPhase (matter)Electronic engineeringPhase-locked loopEngineeringPhysicsComputer scienceControl (management)Artificial intelligencePsychoanalysisQuantum mechanicsImage (mathematics)PsychologyMicrowave Engineering and WaveguidesAcoustic Wave Resonator TechnologiesGaN-based semiconductor devices and materials