Deep Learning-Based Cyclic Shift Keying Spread Spectrum Underwater Acoustic Communication

A deep learning-based cyclic shift keying spread spectrum (CSK-SS) underwater acoustic (UWA) communication system is proposed for improving the performance of the conventional system in low signal-to-noise ratio and multipath effects. The proposed deep learning-based system involves the long- and short-term memory (LSTM) architecture-based neural network model as the receiving module of the system. The neural network is fed with the communication signals passing through known channel impulse responses in the offline stage, and then directly used to demodulate the received signal in the online stage to reduce the influence of the above factors. Numerical simulation and actual data results suggest that the deep learning-based CSK-SS UWA communication system is more reliable communication than a conventional system. In particular, the collected experimental data show that after preprocessing, when the communication rate is less than 180 bps, a bit error rate of less than 10(-3) can be obtained at a signal-to-noise ratio of -8 dB.

Automated summary

A deep learning-based CSK-SS underwater acoustic communication system is proposed to improve performance in low signal-to-noise ratio and multipath effects by utilizing a neural network model. Experimental results show that the system is more reliable than conventional systems, especially when the communication rate is less than 180 bps at a signal-to-noise ratio of -8 dB.