A Lightning Very-High-Frequency Mapping DOA Method Based on L Array and 2D-MUSIC

• Published in: Atmosphere Vol. 16; no. 5; p. 486
• Main Authors: Wang, Chuansheng, Xiang, Nianwen, Li, Zhaokun, Lyu, Zengwei, Yang, Yu, Chen, Huaifei
• Format: Journal Article
• Language: English
• Published: Basel MDPI AG 01.05.2025
• Subjects: 2D-MUSIC; Accuracy; Algorithms; Antennas; Arrays; Azimuth; Broadband; Components; Covariance matrix; Direction of arrival; Discharge; Environmental aspects; Image reconstruction; L-array; Lightning; Lightning channels; Lightning discharges; Localization; Mapping; Methods; Musical performances; Numerical simulations; Observations; Orthogonality; Radiation; radiation source mapping; Radiation sources; Random sampling; Signal classification; Signal processing; Simulation; Spectrum allocation; Subspaces; Very high frequencies; VHF; China
• ISSN: 2073-4433; 2073-4433
• DOI: 10.3390/atmos16050486

Lightning Very-High-Frequency (VHF) radiation source mapping technology represents a pivotal advancement in the study of lightning discharge processes and their underlying physical mechanisms. This paper introduces a novel methodology for reconstructing lightning discharge channels by employing the Multiple Signal Classification (MUSIC) algorithm to estimate the Direction of Arrival (DOA) of lightning VHF radiation sources, specifically tailored for both non-uniform and uniform L-shaped arrays (2D-MUSIC). The proposed approach integrates the Random Sample Consensus (RANSAC) algorithm with 2D-MUSIC, thereby enhancing the precision and robustness of the reconstruction process. Initially, the array data are subjected to denoising via the Ensemble Empirical Mode Decomposition (EEMD) algorithm. Following this, the covariance matrix of the processed array data is decomposed to isolate the signal subspace, which corresponds to the signal components, and the noise subspace, which is orthogonal to the signal components. By exploiting the orthogonality between these subspaces, the method achieves an accurate estimation of the signal incidence direction, thereby facilitating the precise reconstruction of the lightning channel. To validate the feasibility of this method, comprehensive numerical simulations were conducted, revealing remarkable accuracy with elevation and azimuth angle errors both maintained below 1 degree. Furthermore, VHF non-uniform and uniform L-shaped lightning observation systems were established and deployed to analyze real lightning events occurring in 2021 and 2023. The empirical results demonstrate that the proposed method effectively reconstructs lightning channel structures across diverse L-shaped array configurations. This innovative approach significantly augments the capabilities of various broadband VHF arrays in radiation source imaging and makes a substantial contribution to the study of lightning development processes. The findings of this study underscore the potential of the proposed methodology to advance our understanding of lightning dynamics and enhance the accuracy of lightning channel reconstruction.