Novel Decoupling Method Based on Coupling Energy Cancellation and Its Application in 5G Dual-Polarized High-Isolation Antenna Array

A novel decoupling method by utilizing one 1 x 2 subarray to provide a pair of phase-reversed coupling paths for coupling energy cancellation is proposed. The newly proposed decoupling approach is implemented by symmetrically loading several U-type, I-type, and cross strips around the antennas to change the original couplings, so that two elements in the 1 x 2 subarray can form a pair of phase-reversed coupling paths into adjacent element in different subarray for coupling cancellation. Then, the couplings from the subarray to adjacent element are effectively suppressed, thus the isolations between different subarrays of the array are promoted. Moreover, the method can be also applied in improving the isolation between different polarizations in the same subarray. In addition, these strips not only have little influence on radiation characteristics of the antenna array, but also can be etched on the antenna layer without extra profile and process. For demonstration, one dual- polarized patch antenna array based on the new decoupling mechanism is designed. The results indicate that all the isolations between the subarrays of the proposed dual-polarized antenna array can achieve a very high level of over 25 dB in an operation band of 3.4-3.6 GHz. Compared with other decoupling methods, the proposed method can simultaneously improve complex multiple-port isolations among different subarrays and different polarizations to realize a very high isolation with less impact on antenna radiation. Due to above features, the proposed decoupling mechanism is expected to find potential applications in 5G dual-polarized multiple-input-multiple-output (MIMO) antenna array.

Automated summary

This study proposes a novel decoupling method that utilizes a 1 x 2 subarray to provide a pair of phase-reversed coupling paths, effectively improving the isolation between different subarrays and polarizations in an antenna array. The method has little impact on the radiation characteristics of the antenna array and can be implemented directly on the antenna layer, making it highly valuable for potential applications.