Deep Learning-Based Spread-Spectrum FGSM for Underwater Communication

Qasem, Zeyad A. H.; Esmaiel, Hamada; Sun, Haixin; Qi, Jie; Wang, Junfeng

doi:10.3390/s20216134

Cited by 5 publications

(7 citation statements)

References 43 publications

(120 reference statements)

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“…Numerous researchers have started integrating wireless communication with deep learning. [12][13][14] Neural networks have recently shown promise in applying UWAC-OFDM communication, where the channel structure is either unknown or too complicated to be analytically defined. These unknown and complicated channels are analyzed using the recently evolving DL techniques.…”

Section: Introductionmentioning

confidence: 99%

“…Recently, there has been a lot of interest in using deep learning to streamline the architecture of an end‐to‐end communication system. Numerous researchers have started integrating wireless communication with deep learning 12–14 . Neural networks have recently shown promise in applying UWAC‐OFDM communication, where the channel structure is either unknown or too complicated to be analytically defined.…”

Section: Introductionmentioning

confidence: 99%

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Optimized deep learning driven signal detection and adaptive channel estimation in underwater acoustic IoT networks

Kapileswar,

Phani Kumar

2023

Int J Communication

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SummaryNowadays, multiple input multiple outputs with orthogonal frequency division multiplexing (MIMO‐OFDM) provide better communication performance that can be applied to the fast‐growing Internet of Things (IoTs). In underwater IoT, information fades away rapidly due to varying water conditions. Therefore, the MIMO model can be applied to the OFDM acoustic system, enabling high‐speed data transmission without affecting the channel effectively. However, detecting the underwater signal and estimating the channel is highly necessary for enhancing underwater acoustic communication (UWAC). Recently, many techniques have been introduced for effectively performing signal detection and channel estimation. However, those techniques face high time complexity due to increased channel interferences and noises during data transmission. Hence, this article brings a novel technique for SD and CE for the UWAC‐IoT‐enabled MIMO‐OFDM system. An adaptive recursive least square (ARLS) technique is proposed in this study for CE that aids in evaluating the acoustic channel parameters effectively. For performing SD, a bi‐directional deep pelican convolutional neural network (BDPCNN) technique is introduced to ensure the presence and absence of signals at the receiver end. The proposed method is analyzed via the MATLAB platform, and the performances are analyzed under different water types like turbid water, coastal water, clear ocean water, and pure seawater. Different performance metrics like bit error rate (BER), mean square error (MSE), energy efficiency (EE), and time complexity are analyzed with different existing techniques. The experimental section obtains the BER of 0.0086, 0.013, 0.017, and 0.021 for turbid, coastal, clear, and pure seawater, respectively.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Optimized deep learning driven signal detection and adaptive channel estimation in underwater acoustic IoT networks

Kapileswar,

Phani Kumar

2023

Int J Communication

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“…3 Machine learning (ML) offers a new strategy for achieving LPD. 4 Specifically, with recent advances in deep learning (DL), including generative-adversarial networks (GANs), 2 we hypothesize that ML can be used to develop encoding schemes that will be difficult to distinguish from the natural noise-both residing in the RF environment and manifesting in the electronic circuitry of radio receivers.…”

Section: Introductionmentioning

confidence: 99%

Generating Noise-like Communication Codes with Deep Learning

Lee

2023

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“…The deployment of underwater sensor networks (USNs) has enabled extensive marine activities of ocean monitoring and exploring [1,2], in which both underwater acoustic communication (UAC) and underwater wireless optical communication (UWOC) are utilized for underwater networking. Although UAC is the only reliable and dominated technology that currently enables medium and long-range underwater wireless communications, it also suffers from several shortcomings (e.g., limited bandwidth, low-speed, high propagation delay, and high energy consumption [3]), which may make it difficult to meet growing application demands, such as transferring underwater real-time ultra high-definition videos and conducting real-time remotely controlled operations [4,5].…”

Section: Introductionmentioning

confidence: 99%

Reinforcement Learning-Based Adaptive Switching Scheme for Hybrid Optical-Acoustic AUV Mobile Network

Luo

Wang

et al. 2022

Wireless Communications and Mobile Computing

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In an autonomous underwater vehicles– (AUVs–) based optical-acoustic hybrid network, it is critical to achieve ultra high-speed reliable communications, in order to reap the benefits of the complementary systems and perform high-bandwidth and low-latency operations. However, as the mobile AUVs operate in harsh oceanic environments, it is essential to design an effective switching algorithm to execute flexible hybrid acoustic-optical communications and increase the network throughput. In this paper, we propose a Q-learning-based adaptive switching scheme to maximize the network throughput by capturing the dynamics of the varying channels as well as the mobility of AUVs. In order to address the challenge associated with partial observations of the optical channel and improve the switching efficiency in extreme conditions, a blind optical channel estimation method is designed and implemented with the Extended Kalman Filter (EKF), in which the relationship between the underwater acoustic and optical channels is utilized to improve the channel prediction accuracy. Based on this environmental status, a reinforcement learning approach is leveraged to build a near-optimal switching strategy for the hybrid network. We conduct numerical simulations to verify the performance of the scheme, and the simulation results demonstrate that the proposed switching scheme is effective and robust.

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Deep Learning-Based Spread-Spectrum FGSM for Underwater Communication

Cited by 5 publications

References 43 publications

Optimized deep learning driven signal detection and adaptive channel estimation in underwater acoustic IoT networks

Optimized deep learning driven signal detection and adaptive channel estimation in underwater acoustic IoT networks

Generating Noise-like Communication Codes with Deep Learning

Reinforcement Learning-Based Adaptive Switching Scheme for Hybrid Optical-Acoustic AUV Mobile Network

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