MMP-DCD-CV based sparse channel estimation algorithm for underwater acoustic transform domain communication system

Zhang, Youwen; Wu, Tong; Zakharov, Yuriy; Li, Jianghui

doi:10.1016/j.apacoust.2019.04.019

Cited by 12 publications

(8 citation statements)

References 51 publications

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“…However, another threshold has been chosen if the selected threshold has not been given an accurate result, which is a time‐consuming process. Moreover, Zhang et al 36 established the analytically effective multipath matching pursuit (MMP) CE for UWA transform domain communication systems (TDCSs). To resolve the LS problem with lower complexity along with numerical stability, the dichotomous coordinate descent (DCD) iterations have been utilized.…”

Section: Literature Surveymentioning

confidence: 99%

A new optimized least‐square sparse channel estimation scheme for underwater acoustic communication

Kumar

2023

Int J Communication

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Summary In underwater acoustic (UWA) communication, orthogonal frequency division multiplexing (OFDM) is a promising technology that is highly essential to get channel state information meant for channel estimation (CE). Nevertheless, higher complexity, slower convergence, and poor performance, which degrade the performance estimation, are the limitations of the traditional CE methodologies. Thus, by amalgamating the least square (LS)‐CE algorithm along with polynomial interpolated black widow optimization (PI‐BWO) model, an optimized least square sparse (OLSS) CE algorithm has been proposed to intend for a UWA‐OFDM communication system. Formerly, by utilizing the 2's complement shift left turbo encoding (2CSL‐TE) methodology, the input signal is encoded. After that, the modulated encoded signal is provided for inverse fast Fourier transform (IFFT) operations; subsequently, they are transferred over the UWA channel toward the receiver OFDM. By employing the OLSS methodology, the received OFDM signal's interference‐free region is utilized for sparse CE at the receiver. Regarding symbol error rate (SER), bit error rate (BER), mean square error (MSE), and peak signal‐to‐noise ratio (PSNR), the proposed model's experiential outcome is evaluated and analogized with the other prevailing methodologies. When analogized with the conventional models, the proposed estimation methodologies achieved better performance.

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Section: Literature Surveymentioning

confidence: 99%

A new optimized least‐square sparse channel estimation scheme for underwater acoustic communication

Kumar

2023

Int J Communication

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“…T HE detection of different acoustic events is an important task in distinguishing between underwater acoustic (UWA) signals, e.g., marine mammal sounds, UWA communication signals, shipping noise and sonar pulses [1]- [8]. However, the characteristic analysis is usually difficult, because many UWA signals display low signal-to-noise ratio (SNR) or multiple…”

Section: List Of Symbolsmentioning

confidence: 99%

Multimodal Sparse Time–Frequency Representation for Underwater Acoustic Signals

Miao

Sun

2021

IEEE J. Oceanic Eng.

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Multiple features can be extracted from time-frequency representation (TFR) of signals for the purpose of acoustic event detection. However, many underwater acoustic signals are formed by multiple events (impulsive and tonal), which generates difficulty on the high-resolution TFR for each component. For the characterization of such different events, we propose an anisotropic chirplet transform to achieve the TFR with high energy concentration. Such transform applies a time-frequencyvarying Gaussian window to compensate the energy of each component while suppressing unwanted noise. Using a set of directional chirplet ridges from the obtained TFR, a structure-split-merge algorithm is designed to reconstruct a multimodal sparse representation, which provides instantaneous frequency and time features. Specifically, a pulsed-to-tonal ratio, based on these features, is computed to distinguish two acoustic signals. The presented method is validated using shallow water experimental underwater acoustic communication signals, and large sequences of harmonics and pulsed bursts from common whales. Index Terms Anisotropic chirplet transform (ACT), multimodal sparse representation (MSR), pulsed-to-tonal ratio (PTR), time-frequency representation (TFR), underwater acoustic (UWA) signals.

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“…The employed network method is evaluated by the simulation experiment with the signal dataset, which establishes on the real channel arguments in the shallow underwater environment [45]. The underwater testing environment has an average depth of about 53 meters.…”

Section: Experiments a Signal Dataset And Training Parameter Settingmentioning

confidence: 99%

Underwater Communication Signal Recognition Using Sequence Convolutional Network

et al. 2021

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Automatic modulation recognition (AMR) is one of the essential parts in the intelligent communication system. In the underwater acoustic communication, it is a challenging work that promptly and easily recognizes the signal modulation schemes by conventional methods. The deep neural network method is a good solution to the problem, which creates a better recognition effect. The packets of data that are fed to the familiar neural network is constant. However, the packets of signal data on the communication course consistently change, which seriously reflects on the signal recognition veracity. A novel deep learning network with the sequence convolutional network in this paper is proposed, which is composed of one-dimensional sequence convolution of residual network modules and the variable convolution kernel range. By extracting the time-domain signal characteristics, the affection of various signal packets can be mitigated. In experiments, the employed network not only has more concentrated on the modulation recognition veracity, but also owns a lower parameter quantity and a shorter training time, which indicates ideal recognition results in the underwater communication environment. Moreover, it is more valuable to the real underwater communication system.

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MMP-DCD-CV based sparse channel estimation algorithm for underwater acoustic transform domain communication system

Cited by 12 publications

References 51 publications

A new optimized least‐square sparse channel estimation scheme for underwater acoustic communication

A new optimized least‐square sparse channel estimation scheme for underwater acoustic communication

Multimodal Sparse Time–Frequency Representation for Underwater Acoustic Signals

Underwater Communication Signal Recognition Using Sequence Convolutional Network

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