Abstract
Underwater wireless communication is identified by transmission information in random water climates via wireless carriers, such as radiofrequency, and optical waves. Underwater wireless acoustic communication is a central aiding skill used in underwater monitoring with the help of sensor nodes. The sea is often surprised by its fluctuating acoustic signal transmission owing to its portable properties. Such water segments between the transmitter and the receiver are not fixed at any point. Designing Underwater Wireless communication networks is challenging as the water environment is dynamic and tough to implement for underwater applications. We describe an effective, scalable, adaptive Hybrid MIMO-OFDM solution for underwater wireless communications that uses an IDMA strategy to overcome fading limits and increase network performance. OFDM-advantages IDMA's include low-cost iterative multi-user detection, flexible rate adaptation, frequency diversity, and frequency efficiency. We used the MATLAB simulator to simulate our MIMO-OFDM approach with IDMA to alleviate channel noise and fading concerns. Our paper's main goal is divided into two sections. The first step is to connect communication features including BPSK and QAM modulation, Turbo coding, Random Inter leaver, UWMAC, and three routing protocols. We tested our IDMA MIMO-OFDM OFDM implementation with various parameters such as BER, latency, SNR, and energy consumption in the second section. Our suggested IDMA OFDM MIMO technique achieves good BER results but consumes more energy.
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Rani, M., Singal, P. An efficient IDMA-OFDM underwater wireless communication with Reed Solomon and Hamming code. J Opt 51, 456–466 (2022). https://doi.org/10.1007/s12596-021-00800-0
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DOI: https://doi.org/10.1007/s12596-021-00800-0