Robust End-to-End FSO Transmission with Joint Coding Modulation and BiLSTM-Based Channel Modeling under Atmospheric Turbulence

Abstract

Free space optical (FSO) communication is considered a promising solution in nextgeneration communication networks. However, its performance is significantly influenced by atmospheric turbulence. To enhance system robustness to turbulence, we propose a turbulencerobust endtoend FSO communication system (TRFSO) that integrates a data-driven channel model with joint sourcechannel coding modulation (JSCCM). Specifically, a bidirectional long short-term memory (BiLSTM)based channel model is developed and trained on data collected over a physical FSO link under varying turbulence conditions. This model accurately captures realworld channel distortions, achieving a minimum KullbackLeibler (KL) divergence of 0.0019 in amplitude distribution matching. Experimental results show that the TRFSO system trained with the BiLSTMbased channel model outperforms the same architecture trained under the additive white Gaussian noise (AWGN) channel, achieving an average 3.5 dB improvement in multi-scale structural similarity (MSSSIM) under strong atmospheric turbulence. These results demonstrate the effectiveness of the proposed TRFSO in achieving robust and reliable transmission under dynamic atmospheric turbulence.