A Compensation Method for Active Phased Array Antennas : Using a Strain-Electromagnetic Coupling Model
Authors
Shi, YuWang, Congsi
Wang, Yan
Yuan, Shuai
Duan, Baoyan
Lian, Peiyuan
Xue, Song
Du, Biao
Gao, Wei
Wang, Zhihai
Tang, Baofu
Liu, Jing
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Physical deformation due to service loads seriously degrades the electromagnetic performance of active phased array antennas. However, traditional displacement-based compensation methods are moderately difficult to use because displacement measurements generally require stable references, which are hard to realize for antennas in service. For deformed antennas, strain information is directly related to their displacement, and strain sensors can overcome carrier platform constraints to measure real-time strain without affecting the antenna radiation-field distribution. We thus present a compensation method based on strain information for in-service antennas. First, the minimum number of strain sensors is determined as the main modal-order-based modal effective mass fraction. According to the modal method and analysis of spatial phase-distribution errors related to strain, a coupled strain-electromagnetic model is established to evaluate antenna performance from the measured strain. The corresponding excitation phase from the measured strain is adjusted to compensate antenna performance. Finally, the method is experimentally validated using an X-band active phased array antenna under the influence of typical deformation conditions for both boresightand scanned beams. The results demonstrate that the presented method can effectively compensate for the performance of service antennas directly from the measured strain information.Citation
Wang, C., Shi, Y., Tang, B., Liu, J., Wang, Y., Yuan, S., . . . Wang, Z. (2019). A compensation method for active phased array antennas : Using a strain-electromagnetic coupling model. IEEE Antennas and Propagation Magazine.Publisher
IEEEAdditional Links
https://ieeexplore.ieee.org/document/8908709Type
ArticleEISSN
2168-0329ae974a485f413a2113503eed53cd6c53
10.1109/MAP.2019.2950926