Deep Learning-Based Signal Detection for Underwater Acoustic OTFS Communication

Zhang, Yuzhi; Zhang, Shumin; Wang, Bin; Liu, Yang; Bai, Weigang; Shen, Xiaohong

doi:10.3390/jmse10121920

Cited by 11 publications

(5 citation statements)

References 36 publications

(51 reference statements)

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“…Deployment of equipment and establishment of search patterns using the position model: Based on the established position model, design the initial deployment points and search patterns for equipment to minimize the time to locate the missing submersible. Calculate the probability of finding the submersible as a function of time and cumulative search efforts [11] .…”

Section: Problem Restatementmentioning

confidence: 99%

Submersible location prediction using SST turbulence and dynamic analysis

Wang,

Zhou,

Bai

et al. 2024

Third International Symposium on Computer Applications and Information Systems (ISCAIS 2024)

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Submersibles play a vital role in exploring shipwreck sites but face challenges like losing contact with the mother ship and mechanical failures. To address these, a submersible location prediction model was developed based on the turbulence collapse model, utilizing data on the Ionian Sea's currents, density, and terrain. The model incorporates an SST turbulence model, collapse processing, and a dynamic analysis of submersible velocity and displacement, with a state function describing the probability distribution of the submersible's location and an influence function for the next moment. This approach allows for defining uncertainty and suggests submersibles should periodically send their position, environmental parameters, and motion status to the mother ship, equipped with precision sonar, inertial navigation systems, environmental monitoring sensors, and communication devices.

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Section: Problem Restatementmentioning

confidence: 99%

Submersible location prediction using SST turbulence and dynamic analysis

Wang,

Zhou,

Bai

et al. 2024

Third International Symposium on Computer Applications and Information Systems (ISCAIS 2024)

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“…The carrier frequency offset is represented as 𝑓 𝐷 = 𝑣 𝑓 𝑐 𝑐 ⁄ , where 𝑓 𝑐 is the carrier frequency, 𝑐 is the speed of the light and 𝑣 is the speed of the movement between the transceivers [15]. As seen in Table 2, it is considered that the maximum Doppler is set to 1410 Hz, and velocity is set to 380.7 km/h at a carrier frequency of 4 GHz.…”

Section: Table 1 Simulation Parametersmentioning

confidence: 99%

Performance Evaluation of OTFS-NOMA Scheme for High Mobility Users

UMAKOĞLU,

NAMDAR,

BAŞGÜMÜŞ

2023

Sakarya University Journal of Computer and Information Sciences

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Orthogonal Time Frequency Space (OTFS) is a promising approach which is widely employed in sixth generation (6G) wireless network systems. Because of its superior performance in high-mobility environments, OTFS modulation has received a lot of attention lately. Due to OTFS modulation works in the delay-Doppler (DD) domain rather than the conventional time-frequency (TF) domain, it works effectively in such circumstances. The idea of non-orthogonal multiple access (NOMA) is integrated into OTFS as an important approach to improve the spectral efficiency (SE) to investigate the efficiency potential and performance. In this research, we study OTFS modulated NOMA system for two destination users in the high mobility environment. The message passing detection algorithm is utilized to examine bit error rate (BER) performance for both near and far users in the proposed OTFS modulated NOMA system. The BER simulation results demonstrate that the power allocation (PA) coefficient, delays, and Doppler effects significantly impact the performance of the system.

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“…The underwater acoustic communication receiver has a high bit error rate (BER) since it was constructed using the signal characteristics found in the Delay-Doppler feature [11]. The accuracy of signal features may be increased by using deep learning for the feature extraction of signals in the Delay-Doppler domain as the field develops and advances [12]. The Delay-Doppler features of signals are widely used in underwater acoustic communication.…”

Section: Introductionmentioning

confidence: 99%

A Method for Underwater Acoustic Target Recognition Based on the Delay-Doppler Joint Feature

Du,

Wang,

et al. 2024

Remote Sensing

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With the aim of solving the problem of identifying complex underwater acoustic targets using a single signal feature in the Time–Frequency (TF) feature, this paper designs a method that recognizes the underwater targets based on the Delay-Doppler joint feature. First, this method uses symplectic finite Fourier transform (SFFT) to extract the Delay-Doppler features of underwater acoustic signals, analyzes the Time–Frequency features at the same time, and combines the Delay-Doppler (DD) feature and Time–Frequency feature to form a joint feature (TF-DD). This paper uses three types of convolutional neural networks to verify that TF-DD can effectively improve the accuracy of target recognition. Secondly, this paper designs an object recognition model (TF-DD-CNN) based on joint features as input, which simplifies the neural network’s overall structure and improves the model’s training efficiency. This research employs ship-radiated noise to validate the efficacy of TF-DD-CNN for target identification. The results demonstrate that the combined characteristic and the TF-DD-CNN model introduced in this study can proficiently detect ships, and the model notably enhances the precision of detection.

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Deep Learning-Based Signal Detection for Underwater Acoustic OTFS Communication

Cited by 11 publications

References 36 publications

Submersible location prediction using SST turbulence and dynamic analysis

Submersible location prediction using SST turbulence and dynamic analysis

Performance Evaluation of OTFS-NOMA Scheme for High Mobility Users

A Method for Underwater Acoustic Target Recognition Based on the Delay-Doppler Joint Feature

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