Your search keyword '"UNDERWATER acoustics"' showing total 17,023 results

1. Manufacturing of membrane acoustical metamaterials for low frequency noise reduction and control: A review.

Author

Wang, Chao, Cai, Lin, Gao, Mingchen, Jin, Lei, Sun, Lucheng, Tang, Xiaoyun, Shi, Guangyu, Zheng, Xin, and Guo, Chunyu

Subjects

*ABSORPTION of sound, *UNDERWATER acoustics, *NOISE control, *METAMATERIALS, *RESEARCH personnel

Abstract

As a subcategory of acoustic metamaterials, membrane acoustic metamaterials (MAMs) are lighter and more adjustable than other types of acoustic metamaterials when it comes to low-frequency sound absorption. Currently, their primary application is in air mediums. However, there is a small body of research exploring MAMs' underwater potential, as they are expected to offer a solution for controlling low-frequency sound in underwater environments. This review provides an overview of the basic and derived structures of MAMs, and analyses how to adjust the eigenfrequency of both passive and active MAMs to support researchers who are the field of MAMs. [ABSTRACT FROM AUTHOR]

Published

2024

2. Mechanical and physical properties of flexible polyurethane foam filled with waste tire material recycles.

Author

Nezili, Y., El Aboudi, I., He, D., Mdarhri, A., Brosseau, C., Zaghrioui, M., Chartier, T., Ghorbal, A., Arfi, R. Ben, and Bai, J.

Subjects

FOURIER transform infrared spectroscopy, UNDERWATER acoustics, WASTE tires, TIRE treads, TIRE recycling

Abstract

In this work we use ground tire rubber (GTR) powder obtained by grinding worn tire treads as reinforcer agent in flexible polyurethane (PU). Characterization of the microstructure of the as‐received powder is achieved using a series of standard techniques including scanning electron microscopy (SEM), granulometry‐laser, Fourier transform infrared spectroscopy (FTIR), and x‐ray diffraction (XRD). To have complementary physical information the composition and thermal characteristics of the GTR powder, thermogravimetry analysis (TGA) is also performed. The set of these preliminary characterizations shows that the GTR powder particles can be used as reinforcing fillers. For the purpose of good compatibility with the PU matrix, the GTR powder is subjected to chemical treatments for reducing the impurities on the powder particles and to create functional groups at their surface. Subsequently, a series of GTR/PU composite samples are prepared with different weight fractions of GTR using free rising foam method. The GTR/PU composites are then characterized to assess the effect of the GTR content and their chemically pre‐treatment on thermal stability, compression mechanical behavior as well as sound attenuation properties. Collectively, these results indicate a significant improvement of both thermal and mechanical properties of the GTR/PU composites compared to the pristine PU matrix. Furthermore, it is also emphasized that the sound absorption response shows a significant shift of the maximum of the absorption coefficient toward lower frequencies resulting from simultaneous increase in air‐flow resistivity and tortuosity which can have great potential application in the field of underwater acoustics. The effects of chemical treatments and GTR amount are also discussed. It is also shown that the results show improvement when H2O2 solvent is used in comparison with NaOH, and the optimal properties are reached for PU samples containing 20 wt% of GTR whatever the pre‐treatment is. [ABSTRACT FROM AUTHOR]

Published

2024

3. Diversity of solitonic wave structures to the M‐truncated dynamical system in ultrasound imaging.

Author

Yao, Fengping and Younas, Usman

Subjects

*ULTRASONIC imaging, *ULTRASONIC propagation, *THEORY of wave motion, *ACOUSTIC wave propagation, *UNDERWATER acoustics, *CAVITATION, *VIBRATION (Mechanics)

Abstract

The utilization of ultrasound imaging has become extensively prevalent and well‐established in clinical practice. The fundamental technologies that serve as the foundation for various applications in the field include transducers, beam shaping, pulse compression, tissue harmonic imaging, contrast agents, methodologies for quantifying blood flow and tissue motion, and three‐dimensional imaging. This article focuses on the examination of ultrasonic propagation, which involves the transmission of mechanical vibrations within the molecules or particles of a material. It quantifies the velocity of sound propagation in the medium of air. The third‐order nonlinear M‐fractional Westervelt model has been used as a governing model in the imaging process for securing the different wave structures. The recently developed computational methods have been applied in this study. The different wave structures are secured in various forms of solitary wave solutions including bright, dark, and combo solitons. In the domains of medical imaging and therapy, the investigation of sound wave propagation and high‐amplitude phenomena is facilitated by the utilization of wave structures. The effectiveness of these solutions extends to acoustic cavitation, acoustic levitation, underwater acoustics, and facilitating the process of ultrasonic propagation in tissue. Ultrasound imaging technologies currently find application in the medical field, enabling the visualization and examination of internal human tissue. This technology exhibits a wide array of applications in the fields of industry and medicine. A representation of the graphs is produced using the appropriate parametric values. The results suggest that the chosen approaches exhibit effectiveness, viability, and adaptability when implemented in complex systems in various fields, with particular emphasis on ultrasonic imaging. [ABSTRACT FROM AUTHOR]

Published

2024

4. Research on the sub-millisecond underwater electrical wire explosion process.

Author

Liu, Yi, Xu, Youlai, Li, LiuXia, Wang, Tianyu, and Lin, Fuchang

Subjects

*ELECTRIC wire, *EXPLOSIONS, *SHOCK waves, *ELECTRIC wiring, *VAPORIZATION, *UNDERWATER acoustics

Abstract

Underwater electric wire explosion (UEWE) has great potential as a shockwave source for medical and industrial applications. This paper focuses on the process of the sub-millisecond underwater electrical wire explosion (smUEWE). The study compared the smUEWE and the microsecond underwater electrical wire explosion, which revealed the occurrence of partial vaporization under smUEWE, leading to the formation of bamboo-shaped cavities and frontal shock waves. The experiments of smUEWE were carried out under different stored energy, the results indicated the plasma shrinkage and cavity separation during the overall ionization process. Additionally, the study observed secondary breakdown caused by the uneven distribution of ionization products. An analysis was conducted on smUEWE considering partial vaporization, which divided the electrical explosion into a positive feedback process which promoted the axial instability and a negative feedback process which formed the uniform plasma channel. The analysis results was consistent with the experimental results. [ABSTRACT FROM AUTHOR]

Published

2024

5. QiandaoEar22: a high-quality noise dataset for identifying specific ship from multiple underwater acoustic targets using ship-radiated noise.

Author

Du, Xiaoyang and Hong, Feng

Subjects

UNDERWATER acoustics, ACQUISITION of data, DEEP learning, NOISE, RECOGNITION (Psychology), SHIPS

Abstract

Target identification of ship-radiated noise is a crucial area in underwater target recognition. However, there is currently a lack of multi-target ship datasets that accurately represent real-world underwater acoustic conditions. To tackle this issue, we conducted experimental data acquisition, resulting in the release of QiandaoEar22—a comprehensive underwater acoustic multi-target dataset. This dataset encompasses 9 h and 28 min of real-world ship-radiated noise data and 21 h and 58 min of background noise data. To demonstrate the availability of QiandaoEar22, we executed two experimental tasks. The first task focuses on assessing the presence of ship-radiated noise, while the second task involves identifying specific ships within the recognized targets in the multi-ship mixed data. In the latter task, we extracted eight features from the data and employed six deep learning networks for classification, aiming to evaluate and compare the performance of various features and networks. The experimental results reveal that ship-radiated noise can be identified from background noise in over 99% of cases. For the specific identification of individual ships, the optimal recognition accuracy achieves 99.56%. Finally, we found using spectrum and MFCC as feature inputs and DenseNet as classifier can achieve excellent recognition performance. Considering the computational efficiency, CRNN and ECAPA-TDNN are also good choices. Our work not only establishes a benchmark for algorithm evaluation but also inspires the development of innovative methods to enhance underwater acoustic target detection (UATD) and underwater acoustic target recognition (UATR). [ABSTRACT FROM AUTHOR]

Published

2024

6. Underwater Paleotopographic and Geoarchaeological Investigations at Le Castella (Crotone, Italy): New Data on the Late Holocene Coastline Changes and the Presence of Two Disappeared Islets.

Author

Medaglia, Salvatore, Basso, Daniela, Bracchi, Valentina Alice, Bruno, Fabio, Cellini, Emilio, Gaetano, Ercole, Lagudi, Antonio, Mauri, Fabrizio, Megna, Francesco, Rende, Sante Francesco, Severino, Umberto, and Taliano Grasso, Armando

Abstract

A submerged elevation located off the coast of Le Castella, a small village on the Ionian Coast of Calabria (Italy) populated for thousands of years that features notable archaeological remains from the Great Greece (Magna Graecia) and the Middle Ages, was investigated through in-depth, multidisciplinary, geoarchaeological research. This submarine elevation, once aligned with the marine terrace MIS 3 of Le Castella and still completely emerged between 10 and 8 ka years ago, slowly sank due to erosion and local tectonic-structural subsidence and was also favoured by a submerged normal fault that cuts the terrace in two. The dismantling and sinking of this part of the marine terrace has significantly changed the Late Holocene shorelines, with notable consequences on a topographic and archaeological level. In fact, one of the consequences of the sinking of this ancient promontory was the disappearance of two small islands that were reported to be right in front of Le Castella by numerous historical and cartographic sources. In the last decades, there has been a scientific debate over the existence of these islets, but no convincing evidence has been found about their actual presence up until now. This research, funded by the Marine Protected Area "Capo Rizzuto", was conducted by means of underwater archaeological and geological surveys, geophysical seabed mapping systems, and both direct and instrumental optical surveys made with an Autonomous Surface Vehicle. The outcomes allow us to confirm the presence of these two partially emerged rock bodies up to half a millennium ago. In addition, the presence of anthropogenic extrabasinal materials in a marine area corresponding to one of the highest points of the submerged elevation allows us to define the exact position of one of the two islets. These archaeological findings have been subject, for the first time ever, to a thorough topographical and architectural analysis, then compared with other near and very similar submerged structures. On the basis of these comparisons, the findings should be attributed to the Byzantine Age or, at most, to the Middle Ages. In-depth archival research on portolan charts and navigation maps, in many cases unpublished and dating from the Middle Ages to the early 18th century, supports the results of our marine investigations from a historical point of view. [ABSTRACT FROM AUTHOR]

Published

2024

7. Ultra‐broadband sound absorption characteristics in underwater ultra‐thin metamaterial with three layer bubbles.

Author

Gao, Nansha, Huang, Qiaogao, and Pan, Guang

Subjects

ABSORPTION of sound, UNDERWATER acoustics, FINITE element method, TRANSFER matrix, ABSORPTION coefficients

Abstract

The interest of this article is to obtain the underwater broadband sound absorption characteristics by filling three layers of bubbles in Polydimethylsiloxane polymer (PDMS). In this underwater ultra‐thin metamaterial, three‐layer bubbles are arranged from small to large with the same radius center. The finite element analysis (FEA) method and transfer matrix (TM) method have good consistency in calculating the sound absorption coefficient of this metamaterial. The results reveals that sub‐wavelength metamaterial properties can be achieved below 6.4 MHz. Bubble coupling critical viscosity, waning coupling between layers, waveform transformation, and increasing scattering (reflection) waves all affect broadband sound absorption characteristics. The position and size of three bubbles are discussed, and design summary could be potentially in underwater ultrasound filter devices and medical ultrasound field. [ABSTRACT FROM AUTHOR]

Published

2024

8. Janus Metasurface for Underwater Sound Manipulation.

Author

Li, Chen‐Yang, Zhou, Hong‐Tao, Li, Xiao‐Shuang, Wang, Yan‐Feng, and Wang, Yue‐Sheng

Subjects

*UNIT cell, *ACOUSTIC devices, *ACOUSTIC wave propagation, *TOPOLOGY, *UNDERWATER acoustics

Abstract

Bidirectional controllable propagation of waterborne sound holds significant importance in developing multifunctional underwater acoustic and mechanical devices. However, the existing waterborne acoustic metasurfaces have rarely explored the bidirectional sound modulations. Here, a class of Janus waterborne acoustic metasurface, enabling two‐faced arbitrarily asymmetric wavefront manipulations is reported. A three‐degree‐of‐freedom mechanical system facilitated by acoustic‐structure interaction underwater is proposed to introduce bianisotropic responses of unit cells. Monolayer ultrathin Janus metasurface is inversely designed by utilizing a function‐structure integrated topology optimization framework. Distinct underwater acoustic functionalities, including axial and oblique focusing, beam splitting, and sound diffusion, are successfully demonstrated. Underwater experiments are further conducted to validate the concept of Janus metasurface. The good consistency between experimental and simulated results confirms the excellent two‐faced asymmetric acoustic focusing performance. The proposed Janus metasurface opens up a new dimension for designing advanced waterborne acoustic devices with two‐faced multifunctional wavefront manipulations. [ABSTRACT FROM AUTHOR]

Published

2024

9. Performance Analysis of MIMO Based ERPO-OFDM Using Optical-Acoustic Channel in Underwater Communication.

Author

Anitha Vijayalakshmi, B., Arunsundar, B., Tamizhselvan, C., and Nesasudha, M.

Subjects

ORTHOGONAL frequency division multiplexing, BIT error rate, FACE-to-face communication, LIGHT emitting diodes, UNDERWATER acoustics, OPTICAL communications

Abstract

Underwater wireless communication stands as a captivating and swiftly progressing domain in recent. To support higher data rate and higher bandwidth applications, there is significant attention towards underwater acoustics along with Visible Light Communication (VLC) technology. Underwater sensor networking serves as the backbone of oceanic exploration efforts. Based on the traffic load and underwater environmental conditions, an appropriate communication link can be selected to achieve higher data rate. Acoustics supports communication over longer distances with lower data rate. Despite offering higher data rates, Visible Light Communication (VLC) faces limitations in terms of communication range, proving to be relatively short compared to other methods. A seamless transition is anticipated during data transmission and reception by employing Light Emitting Diodes (LEDs) and photo detectors on the optical-acoustic channel, bridging the gap between acoustic and optical communication methods. Utilizing MIMO-based Enhanced Reverse Polarity Orthogonal Frequency Division Multiplexing (MIMO-ERPO-OFDM) in Underwater Optical Communication (UWOC) proves to be a superior approach, achieving a high throughput of 19.9 Mbps and a lower Bit Error Rate (BER) of 10− 1. [ABSTRACT FROM AUTHOR]

Published

2024

10. QiandaoEar22: a high-quality noise dataset for identifying specific ship from multiple underwater acoustic targets using ship-radiated noise

Author

Xiaoyang Du and Feng Hong

Subjects

Underwater acoustic dataset, Underwater target recognition, Underwater acoustics, Deep learning, Telecommunication, TK5101-6720, Electronics, TK7800-8360

Abstract

Abstract Target identification of ship-radiated noise is a crucial area in underwater target recognition. However, there is currently a lack of multi-target ship datasets that accurately represent real-world underwater acoustic conditions. To tackle this issue, we conducted experimental data acquisition, resulting in the release of QiandaoEar22—a comprehensive underwater acoustic multi-target dataset. This dataset encompasses 9 h and 28 min of real-world ship-radiated noise data and 21 h and 58 min of background noise data. To demonstrate the availability of QiandaoEar22, we executed two experimental tasks. The first task focuses on assessing the presence of ship-radiated noise, while the second task involves identifying specific ships within the recognized targets in the multi-ship mixed data. In the latter task, we extracted eight features from the data and employed six deep learning networks for classification, aiming to evaluate and compare the performance of various features and networks. The experimental results reveal that ship-radiated noise can be identified from background noise in over 99% of cases. For the specific identification of individual ships, the optimal recognition accuracy achieves 99.56%. Finally, we found using spectrum and MFCC as feature inputs and DenseNet as classifier can achieve excellent recognition performance. Considering the computational efficiency, CRNN and ECAPA-TDNN are also good choices. Our work not only establishes a benchmark for algorithm evaluation but also inspires the development of innovative methods to enhance underwater acoustic target detection (UATD) and underwater acoustic target recognition (UATR).

Published

2024

11. Pressure effects on the resonant attenuation of soft porous beads-based materials for underwater acoustics.

Author

Lacour, Thomas, Poupart, Romain, Mondain-Monval, Olivier, Aristégui, Christophe, Poncelet, Olivier, and Brunet, Thomas

Subjects

*POROUS materials, *UNDERWATER acoustics, *STRAINS & stresses (Mechanics), *HYDROSTATIC pressure, *ALKYL compounds, *ACOUSTIC devices

Abstract

Dedicated coating materials for anechoism and furtivity in underwater acoustics must exhibit a strong reliability regarding their mechanical resistance to hydrostatic pressure. Soft porous materials, especially, a distribution of soft porous beads within a polyurethane matrix, have been previously proposed as an acoustic insulator device. The purpose of the present letter is to investigate the attenuation efficiency of soft porous silicone beads-based materials while being exposed to uniaxial loads mimicking hydrostatic pressures encountered in underwater acoustics. The acoustic performance of this locally resonant material is then compared to the classical coating technology using micro-balloons. The use of an adapted surfactant (a silicone alkyl polyether compound) in the fabrication process of the soft porous silicone-based beads, obtained through an emulsion templating process, leads to particles exhibiting an open porosity. The (resonant) attenuation of the soft porous beads-based material remains greater than the micro-balloons-based material until several bars. Above this critical resilience value, the mechanical stress irreversibly damages the soft porous beads. [ABSTRACT FROM AUTHOR]

Published

2023

12. Observation of Ultra‐High‐Q Resonators in the Ultrasound via Bound States in the Continuum.

Author

Farhat, Mohamed, Achaoui, Younes, Martínez, Julio Andrés Iglesias, Addouche, Mahmoud, Wu, Ying, and Khelif, Abdelkrim

Subjects

*UNDERWATER acoustics, *WAVES (Physics), *ULTRASONIC waves, *SOUND waves, *QUALITY factor

Abstract

The confinement of waves in open systems represents a fundamental phenomenon extensively explored across various branches of wave physics. Recently, significant attention is directed toward bound states in the continuum (BIC), a class of modes that are trapped but do not decay in an otherwise unbounded continuum. Here, the theoretical investigation and experimental demonstration of the existence of quasi‐bound states in the continuum (QBIC) for ultrasonic waves are achieved by leveraging an elastic Fabry–Pérot metasurface resonator. Several intriguing properties of the ultrasound quasi‐bound states in the continuum that are robust to parameter scanning are unveiled, and experimental evidence of a remarkable Q‐factor of 350 at ≈1 MHz frequency, far exceeding the state‐of‐the‐art using a fully acoustic underwater system is presented. The findings contribute novel insights into the understanding of BIC for acoustic waves, offering a new paradigm for the design of efficient, ultra‐high Q‐factor ultrasound devices. [ABSTRACT FROM AUTHOR]

Published

2024

13. Multichannel Wiener filter in active sound‐navigation‐and‐ranging systems—A joint beamformer and matched filter approach.

Author

Kaulen, Bastian, Abshagen, Jan, and Schmidt, Gerhard

Subjects

*BEAMFORMING, *MATCHED filters, *UNDERWATER acoustics, *SIGNAL processing, *SIGNAL filtering

Abstract

Conventional active SONAR systems often use beamformers and matched filters separately to extract bearing and range information from the received signal and offer a straightforward way of creating a two‐dimensional map of the environment. In SONAR systems the minimum‐variance‐distortionless‐response beamformer (MVDR beamformer) is a commonly used type of beamformer, which will reconstruct the receive signal from a certain direction optimally. In terms of detecting the transmit signal, the most used method is the conventional matched filter. Both algorithms are simple to implement and perform well under various noise scenarios. The proposed method combines the beamformer and matched filter by introducing an extended channel model that allows the derivation of a multichannel Wiener filter to solve for the unknown reflection coefficients of the complete two‐dimensional environment. This results in adaptively calculated filter weights that will drastically improve the performance compared to a separate MVDR beamformer and matched filter. In addition, a parameter is introduced with which one can arbitrarily adjust the focus between angular and temporal resolution depending on the application. After the derivation, the performance is demonstrated with simulations and measurements. [ABSTRACT FROM AUTHOR]

Published

2024

14. Longitudinal low-frequency vibration control of a propeller-shafting system using a hydraulic leveraged dynamic anti-resonance vibration isolator: A theoretical and experimental study.

Author

Liu, Niuniu, Lei, Xianliang, and Xue, Xin

Subjects

*ACOUSTIC radiation, *VIBRATION isolation, *UNDERWATER acoustics, *ELASTICITY, *PROPELLERS

Abstract

The longitudinal fluctuating forces of a propeller are a major cause of sound radiation of an underwater vehicle in the low frequency range. A hydraulic leveraged dynamic anti-resonance vibration isolator (HLVI) is proposed to attenuate the longitudinal vibration of a shaft system transmitted to the hull. The semi-analytical model of the shafting system with and without the isolator is set up by employing the frequency response synthesis method, in which the elasticity of the foundation is taken into consideration. Compared to the traditional isolation scheme and DVA, the proposed control scheme will not change the longitudinal effective stiffness and needs a small mass to attenuate the longitudinal vibration of the shafting system. A parametric study was conducted to investigate the key parameters of the isolator and their impact on its isolation performance. An experimental apparatus is set up to validate the isolation scheme. The acceleration frequency response results of the shafting system under axial excitation with both the frequency sweep method and discrete sinusoidal frequencies are presented and discussed. The results indicate that the proposed method is capable of attenuating the corresponding longitudinal vibration of the shafting system. [ABSTRACT FROM AUTHOR]

Published

2024

15. Information Geometry in Underwater Acoustics: Tutorial, Case Study, and Outlook.

Author

Spendlove, Jay C., Mortenson, Michael C., Neilsen, Tracianne B., and Transtrum, Mark K.

Subjects

*OPTIMAL designs (Statistics), *UNDERWATER acoustics, *DIFFERENTIAL geometry, *FISHER information, *INFORMATION theory

Abstract

This tutorial demonstrates the use of information geometry tools in analyzing environmental parameter sensitivities in underwater acoustics. Sensitivity analyses quantify how well data can constrain model parameters, with application to inverse problems like geoacoustic inversion. A review of examples of parameter sensitivity methods and their application to problems in underwater acoustics is given, roughly grouped into "local" and "non-local" methods. Local methods such as Fisher information and Cramér-Rao bounds have important connections to information geometry. Information Geometry combines the fields of information theory and differential geometry by interpreting a model as a Riemannian manifold, known as the model manifold, that encodes both local and global parameter sensitivities. As an example, 2-dimensional model manifold slices are constructed for the Pekeris waveguide with sediment attenuation, for a vertical array of hydrophones. This example demonstrates how effective, reduced-order models emerge in certain parameter limits, which correspond to boundaries of the model manifold. This example also demonstrates how the global structure of the model manifold influences the local sensitivities quantified by the Fisher information matrix. This paper motivates future work to utilize information geometry methods for experimental design and model reduction applied to more complex modeling scenarios in underwater acoustics. [ABSTRACT FROM AUTHOR]

Published

2024

16. Implementation of the split-beam function to Mills cross multibeam echo sounder for target strength measurements.

Author

Matte, Guillaume, Gauthier, Tehei, Rousselot, Nathan, Guillard, Jean, Lamouret, Marie, Lerda, Olivier, Tallon, Benoit, Roux, Phillipe, and Mosca, Frederic

Subjects

*ECHO sounders, *FISH populations, *SONAR, *DATA quality, *UNDERWATER acoustics

Abstract

Modern challenges in the increasing exploitation of aquatic ecosystems require efficient, reliable, and noninvasive technologies to acquire biomass information on a large scale. For the past 40 years, hydroacoustics has been an essential tool to analyse fish populations and their relationship with the environment. Currently, split-beam echo sounders are standard tools used to reliably and accurately record data in oceans, estuaries, and lakes. To maximize the coverage volume and to increase target detection, and therefore data quality, the use of multi-beam echo sounders is a real asset. We propose here an innovative method for target strength (TS) calculation based on the signal from a reversible Mills cross multi-beam sonar, SeapiX (Exail), which also includes the analytical capability of a split-beam echo sounder. This innovative approach provides new original information when using a multi-beam sonar. The case study in Lake Bourget was based on a comparison of the simultaneous recordings of SeapiX and EK80 (SIMRAD) to prove the validity of this multi split-beam processing, as well as to estimate the in situ TS of fish. [ABSTRACT FROM AUTHOR]

Published

2024

17. Source and propagation modelling scenarios for environmental impact assessment: Model verificationa).

Author

Ainslie, Michael A., Laws, Robert M., Smith, Michael J., and MacGillivray, Alexander O.

Subjects

*ENVIRONMENTAL impact analysis, *UNDERWATER acoustics, *ACOUSTIC field, *ACOUSTIC wave propagation, *ECHO sounders

Abstract

Evaluation of possible effects of underwater sound on aquatic life requires quantification of the sound field. A marine sound source and propagation modelling workshop took place in June 2022, whose objectives were to facilitate the evaluation of source and propagation models and to identify relevant metrics for environmental impact assessment. The scope of the workshop included model verification (model-model comparison) and model validation (model-measurement comparison) for multiple sources, including airguns, a low-frequency multi-beam echo sounder, and a surface vessel. Several verification scenarios were specified for the workshop; these are described herein. [ABSTRACT FROM AUTHOR]

Published

2024

18. Improvement of a Green's Function Estimation for a Moving Source Using the Waveguide Invariant Theory.

Author

Kim, Daehwan, Kim, Donghyeon, Byun, Gihoon, Kim, Jeasoo, and Song, Heechun

Subjects

*GREEN'S functions, *UNDERWATER acoustics, *IMPULSE response, *ACOUSTIC models, *SIGNAL-to-noise ratio

Abstract

Understanding the characteristics of underwater sound channels is essential for various remote sensing applications. Typically, the time-domain Green's function or channel impulse response (CIR) is obtained using computationally intensive acoustic propagation models that rely on accurate environmental data, such as sound speed profiles and bathymetry. Ray-based blind deconvolution (RBD) offers a less computationally demanding alternative using plane-wave beamforming to estimate the Green's function. However, the presence of noise can obscure low coherence ray arrivals, making accurate estimation challenging. This paper introduces a method using the waveguide invariant to improve the signal-to-noise ratio (SNR) of broadband Green's functions for a moving source without prior knowledge of range. By utilizing RBD and the frequency shifts from the striation slope, we coherently combine individual Green's functions at adjacent ranges, significantly improving the SNR. In this study, we demonstrated the proposed method via simulation and broadband noise data (200–900 Hz) collected from a moving ship in 100 m deep shallow water. [ABSTRACT FROM AUTHOR]

Published

2024

19. Pseudoreplication of sound treatments in underwater exposure studies.

Author

Hubert, Jeroen, Willems, Max, and Varkevisser, Judith M.

Subjects

*UNDERWATER acoustics, *ACOUSTICS, *SOUND design, *EXPERIMENTAL design, *NOISE

Abstract

Sound exposure studies require replicated sound treatments for the results to be representative for sound classes in general. Additionally, reused treatments in replicated designs need to be accounted for statistically. The lack hereof is referred to as simple and sacrificial pseudoreplication, respectively, and results should be interpreted accordingly. We quantified the occurrence of these issues and subsequent interpretation of results in 104 underwater sound exposure studies (2019–2023). The majority of the studies (85%) did not replicate sound treatments. From the ones that did, most did not statistically acknowledge the hierarchical structure of the data. Unreplicated treatment designs limit the generalizability of the findings. Nevertheless, only small differences were found in how the results of unreplicated and replicated treatment designs were interpreted. This commentary aims to provide guidance in the design, analysis and interpretation of sound exposure studies, which are equally valid for aquatic and terrestrial research. • We quantified sound treatment pseudoreplication in underwater sound exposure studies. • Most papers did not replicate sound treatments (simple pseudoreplication). • Hierarchical treatment designs were often not statistically acknowledged. • We hope to contribute to reducing pseudoreplication in sound exposure studies. [ABSTRACT FROM AUTHOR]

Published

2024

20. The Brazilian Santos basin underwater soundscape monitoring project (PMPAS-BS).

Author

Moreira Lima, José Antonio, Soares Filho, William, Xavier, Fabio C., Pires de Paula, Thiago, Spengler, Angela, Gonçalves de Almeida, Fernando, Correa Pereira, Diogo Peregrino, Souza Rego, Valéria, Galotta, Cátia, Corrêa Junior, Carlos, and Bazyl, Alexandre

Subjects

UNDERWATER noise, NOISE, SEDIMENTARY basins, ACOUSTIC measurements, UNDERWATER acoustics, EMISSION control, ACOUSTIC emission testing

Abstract

This paper describes the Santos Basin Underwater Soundscape Monitoring Project (PMPAS-BS), a Brazilian ocean soundscape monitoring initiative. The main objective of the project is to quantify and assess hydroacoustic noise of anthropogenic origin in a large sedimentary basin extending from 23° S to 28° S on the southeastern Brazilian continental margin of the South Atlantic Ocean. Noise associated with oil and gas (O&G) exploration and production activities is the primary target, but this oceanic region also has busy shipping lanes for commercial, military, and fishing vessels. The two main hubs of Brazil’s export and import of goods by sea are located in this region: Santos and Rio de Janeiro ports. The project has three measurement components: mobile monitoring based on gliders and drifting acoustic profilers, fixed shallow-water monitoring based on acoustic measurements at coastal stations near shipping lanes associated with exploration and production activities in the Santos Basin, and fixed oceanic monitoring based on deep-water mooring lines equipped with passive autonomous acoustic recorders near production units, shipping lanes, and areas with lower intensity of O&G activities (pristine or reference sites). Numerical modeling of anthropogenic underwater acoustic noise has also been included as a fourth project component. The PMPAS-BS covers an area of more than 251,000 km² and uses several instruments with different methods and sensors for acoustic measurements. Its results provide current sound levels over a very large region of the western South Atlantic, both in areas more and less affected by anthropogenic activities. [ABSTRACT FROM AUTHOR]

Published

2024

21. Study on the Ensuring of Reliability and Repeatability of Research in the Area of Marine Ecology through Calibration of Underwater Acoustics Devices.

Author

Listewnik, Karol Jakub and Mindykowski, Janusz

Subjects

ACOUSTIC measurements, UNDERWATER acoustics, MARINE ecology, FISHERY sciences, FISHERIES

Abstract

This paper emphasizes the crucial needs and reasons to ensure the reliability and repeatability of underwater acoustic measurements. As an exemplification of the aforementioned acoustic measurements challenges, the development of metrological infrastructure in the area of underwater acoustics in GUM (Central Office of Measures, Poland) is presented. An analysis of presented solutions was carried out mainly in the low frequency range, in comparison with other solutions recently developed worldwide. Moreover, factors influencing the sensitivity of hydroacoustic measuring devices are discussed. The summary of this discussion outlines the further works aimed at ensuring the reliability and repeatability of underwater acoustic measurements. The conclusions present the current state of the calibration infrastructure of underwater acoustic devices, with particular emphasis on marine ecology and fisheries sciences. [ABSTRACT FROM AUTHOR]

Published

2024

22. Estimation of Source Range and Location Using Ship-Radiated Noise Measured by Two Vertical Line Arrays with a Feed-Forward Neural Network.

Author

Jo, Moon Ju, Choi, Jee Woong, and Han, Dong-Gyun

Subjects

MACHINE learning, CROSS correlation, ACOUSTIC radiators, COVARIANCE matrices, ACOUSTIC models, UNDERWATER acoustics

Abstract

Machine learning-based source range estimation is a promising method for enhancing the performance of tracking both the dynamic and static positions of targets in the underwater acoustic environment using extensive training data. This study constructed a machine learning model for source range estimation using ship-radiated noise recorded by two vertical line arrays (VLAs) during the Shallow-water Acoustic Variability Experiment (SAVEX-15), employing the Sample Covariance Matrix (SCM) and the Generalized Cross Correlation (GCC) as input features. A feed-forward neural network (FNN) was used to train the model on the acoustic characteristics of the source at various distances, and the range estimation results indicated that the SCM outperformed the GCC with lower error rates. Additionally, array tilt correction using the array invariant-based method improved range estimation accuracy. The impact of the training data composition corresponding to the bottom depth variation between the source and receivers on range estimation performance was also discussed. Furthermore, the estimated ranges from the two VLA locations were applied to localization using trilateration. Our results confirm that the SCM is the more appropriate feature for the FNN-based source range estimation model compared with the GCC and imply that ocean environment variability should be considered in developing a general-purpose machine learning model for underwater acoustics. [ABSTRACT FROM AUTHOR]

Published

2024

23. Predictions of the Effect of Non-Homogeneous Ocean Bubbles on Sound Propagation.

Author

Cheng, Yuezhu, Shi, Jie, Cao, Yuan, and Zhang, Haoyang

Subjects

SOUND wave scattering, MULTIPLE scattering (Physics), ACOUSTIC field, UNDERWATER acoustics, THEORY of wave motion, ACOUSTIC wave propagation

Abstract

In the ocean, bubbles rarely appear alone and are often not evenly distributed, which makes it complicated to predict the effect of ocean bubbles on sound propagation. To solve this problem, researchers have tried to use approximations such as equivalent and multiple scattering models, but these approximations are accompanied by large errors. Therefore, we propose a semi-numerical and semi-analytical calculation method for underwater sound fields containing non-homogeneous bubbles in this paper. Based on the attenuation cross section and scattering cross section of a single bubble, the non-homogeneous medium is divided into multiple layers of uniform medium. Each layer of the bubble group is regarded as a whole, which can fully reflect the influence of bubble group vibration and scattering on sound wave propagation and is conducive to faster calculation of the sound field of non-homogeneous bubbly liquids. Compared with the classic coupling model, the calculation process of this method is simpler and faster, which solves the problem of fast calculation of sound fields in bubbly liquids and simulation of distributed bubble groups containing non-homogeneous distributed bubbles. [ABSTRACT FROM AUTHOR]

Published

2024

24. A Normal Mode Model Based on the Spectral Element Method for Simulating Horizontally Layered Acoustic Waveguides.

Author

Zhang, Yinuo, Tu, Houwang, Wang, Yongxian, Xu, Guojun, and Gao, Dongbao

Subjects

NUMERICAL solutions to equations, FINITE difference method, ACOUSTIC waveguides, COMPUTATIONAL acoustics, UNDERWATER acoustics, SPECTRAL element method

Abstract

Acoustic waves are essential tools for guiding underwater activities. For many years, numerical modeling of ocean acoustic propagation has been a major research focus in underwater acoustics. Normal mode theory, one of the earliest and most extensively studied methods in this field, is renowned for its well-established theoretical framework. The core of normal mode theory involves the numerical solution of modal equations. In classical normal mode models, these equations are typically discretized using low-order finite difference methods, which, while broadly applicable, suffer from a limited convergence rate. The spectral element method, widely used in the seismic field, is recognized for its spectral precision and flexibility. In this article, we propose a normal mode model discretized using the spectral element method. The weak form of the modal equation directly satisfies boundary and interface conditions without requiring additional operations. The entire computational domain can be divided into segments of varying number and length, configured according to environmental conditions. The perfectly matched layer technique is employed to simulate acoustic half-space boundary conditions, effectively addressing the high computational costs and numerical instability associated with traditional artificial absorbing layers. Based on these algorithms, we have developed a numerical program (SEM). This research verifies the accuracy of the spectral element model through three different types of numerical experiments. [ABSTRACT FROM AUTHOR]

Published

2024

25. Modeling the Underwater Sound of Floating Offshore Windfarms in the Central Mediterranean Sea.

Author

Baldachini, Marzia, Burns, Robin D. J., Buscaino, Giuseppa, Papale, Elena, Racca, Roberto, Wood, Michael A., and Pace, Federica

Subjects

UNDERWATER acoustics, SUSTAINABILITY, CLEAN energy, ACOUSTICS, WIND power plants, OFFSHORE wind power plants

Abstract

In the shift toward sustainable energy production, offshore wind power has experienced notable expansion. Several projects to install floating offshore wind farms in European waters, ranging from a few to hundreds of turbines, are currently in the planning stage. The underwater operational sound generated by these floating turbines has the potential to affect marine ecosystems, although the extent of this impact remains underexplored. This study models the sound radiated by three planned floating wind farms in the Strait of Sicily (Italy), an area of significant interest for such developments. These wind farms vary in size (from 250 MW to 2800 MW) and environmental characteristics, including bathymetry and seabed substrates. Propagation losses were modeled in one-third-octave bands using JASCO Applied Sciences' Marine Operations Noise Model, which is based on the parabolic equation method, combined with the BELLHOP beam-tracing model. Two sound speed profiles, corresponding to winter and summer, were applied to simulate seasonal variations in sound propagation. Additionally, sound from an offshore supply ship was incorporated with one of these wind farms to simulate maintenance operations. Results indicate that sound from operating wind farms could reach a broadband sound pressure level (Lp) of 100 dB re 1 µPa as far as 67 km from the wind farm. Nevertheless, this sound level is generally lower than the ambient sound in areas with intense shipping traffic. The findings are discussed in relation to local background sound levels and current guidelines and regulations. The implications for environmental management include the need for comprehensive monitoring and mitigation strategies to protect marine ecosystems from potential acoustic disturbances. [ABSTRACT FROM AUTHOR]

Published

2024

26. Underwater Acoustic Camouflage by Wettability Transition on Laser Textured Superhydrophobic Metasurfaces.

Author

Mezzapesa, Francesco P., Gaudiuso, Caterina, Volpe, Annalisa, Ancona, Antonio, Mauro, Salvatore, and Buogo, Silvano

Subjects

SOUND-wave attenuation, SPECTRAL sensitivity, ACOUSTIC field, METASTABLE states, ACOUSTICAL materials

Abstract

The superhydrophobicity of submerged surfaces typically pertains to the trapped air film at the liquid–solid interface, subject to wettability transitions from a Cassie–Baxter state to more unstable states that gradually collapse to high retention regimes, which are energetically more favorable. In this work, the dynamic evolution of those transient metastable states is correlated to the underwater acoustic performance of laser textured superhydrophobic surfaces, resolving the dependence of the ultrasound spectral response with the immersion time to capture the genuine contribution of the hierarchical subwavelength morphology, regardless of the air layer effects. Acoustic wave attenuation of the incident ultrasound energy is extensively quantified in transmission, accounting for instantaneous broadband sound blocking (>30 dB) within the spectral range 0.5–1.5 MHz. As a result of the air layer detachment with the immersion time, transmission coefficients increase accordingly, while acoustic fields in reflection unexpectedly evolve toward stealthiness and naïve acoustic camouflage, mostly ascribable to dissipative mechanisms at air layer interfaces. The intrinsic decay of the air layer effect is tentatively determined at different frequencies, since quantitative understanding of the transient lifetime governing underwater surface wettability is critical to design stable superhydrophobic character of laser induced subwavelength metastructures on the most promising acoustic materials – from eco‐friendly natural to artificial. [ABSTRACT FROM AUTHOR]

Published

2024

27. Underwater Long Baseline Positioning Based on B-Spline Surface for Fitting Effective Sound Speed Table.

Author

Xing, Yao, Wang, Jiongqi, Hou, Bowen, He, Zhangming, and Zhou, Xuanying

Subjects

SPEED of sound, PARTICLE swarm optimization, UNDERWATER acoustics, UNDERWATER navigation, SURFACE analysis

Abstract

Due to the influence of the complex underwater environment, the sound speed constantly changes, resulting in the acoustic signal propagation trajectory being curved, which greatly affects the positioning accuracy of the underwater long baseline (LBL) system. In this paper, an improved LBL positioning method based on a B-spline surface for fitting the effective sound speed table (ESST) is proposed. Firstly, according to the underwater sound speed profile, the discrete ESST of each measurement station is constructed before the positioning test, and then, the node position of the B-spline surface is optimized by particle swarm optimization (PSO) to accurately fit the discrete ESST. Based on this, the improved LBL positioning method is constructed. In the underwater positioning test, the effective sound speed can be quickly found by measuring the time of arrival (TOA) of the acoustic signal and the target depth, and moreover, the target position parameters can be quickly and accurately estimated. The numerical simulation results show that the improved positioning method proposed in this paper can effectively improve the LBL positioning accuracy and provide the theoretical basis and the technical support for the underwater navigation and positioning. [ABSTRACT FROM AUTHOR]

Published

2024

28. Automatic modulation identification for underwater acoustic signals based on the space–time neural network.

Author

Yaohui Lyu, Xiao Cheng, and Yan Wang

Subjects

UNDERWATER acoustics, AUTOMATIC identification, UNDERWATER acoustic communication, TRANSFORMER models, SPACETIME, FEATURE extraction

Abstract

In general, CNN gives the same weight to all position information, which will limit the expression ability of the model. Distinguishing modulation types that are significantly affected by the underwater environment becomes nearly impossible. The transformer attention mechanism is used for the feature aggregation, which can adaptively adjust the weight of feature aggregation according to the relationship between the underwater acoustic signal sequence and the location information. In this paper, a novel aggregation network is designed for the task of automatic modulation identification (AMI) in underwater acoustic communication. It is feasible to integrate the advantages of both CNN and transformer into a single streamlined network, which is productive and fast for signal feature extraction. The transformer overcomes the constraints of sequential signal input, establishing parallel connections between different modulations. Its attention mechanism enhances the modulation recognition by prioritizing the key information. Within the transformer network, the proposed network is strategically incorporated to form a spatial–temporal structure. This structure contributes to improved classification results, and it can obtain more deep features of underwater acoustic signals, particularly at lower signal-to-noise ratios (SNRs). The experiment results achieve an average of 89.4% at −4 dB ≤ SNR ≤ 0 dB, which exceeds other state-of-the-art neural networks. [ABSTRACT FROM AUTHOR]

Published

2024

29. Observation and modeling of an unusual spatiotemporal pattern in bioacoustic chorusing.

Author

D'Spain, Gerald L., Rovner, Galina L., Batchelor, Heidi, and Rimington, Dennis B.

Subjects

UNDERWATER acoustics, ACOUSTIC field, TERRITORIAL waters, CELLULAR automata, WATER depth, BEACHES

Abstract

This paper describes an unusual underwater biological chorus recorded in the Southern California Bight and presents a numerical modeling approach that replicates aspects of the chorus. During one experiment, the evolution of the directionality of the chorusing region over time is suggestive of "The Wave", the human waves performed by fans periodically standing and sitting in sports stadia around the world; here, the region of chorusing periodically propagated upcoast over 20 km of coastline at nearly 1.5 km/s. The chorus occurs predominantly at night in spring and summer, mostly in very shallow waters near the coast. It increases the underwater sound field levels within chorusing regions by 20-30 dB in the 50 Hz to 1 kHz frequency band. The chorus is composed of three parts; 1) a "sunset chorus" which is a 20-to-30 min continuous roar around sunset with received spectral levels up to 100 dB re 1 µPa²/Hz, 2) a "sunrise chorus" of lower level than the sunset chorus, and 3) an all-night-long cycling chorus. The cycling portion is made up of 15-to-20 s periods of higher received spectral levels (up to 90 dB re 1 µPa²/Hz within the chorusing region) each followed by a 10-to-20 s lull in which the spectral levels drop by 4-10 dB. This alternating pattern repeats every 30-40 s throughout the night. The numerical modeling approach is based on the physics of excitable media. A cellular automaton is used to model the two-dimensional spatial grid occupied by the calling animals (units), with each unit being either in the "resting", "excitable", or "active (calling)" state at each time step. Transition from resting to excitable and from active back to resting occurs automatically after a fixed period of time in the present state, whereas the probability of transitioning from excitable to active is determined not only by the elapsed time since entering the excitable state, but also by the received sound level at the unit location, creating a non-linear acoustics-based coupling between units. With appropriate inputs, many determined from measurements of the chorus properties and the individual animal calls themselves, simulations with the model can replicate the cycling levels in the night-long chorus, the continuous din of the sunset chorus, and (once properly initialized) the periodic upcoast evolution of the chorusing region ("The Wave"). When noise from a transiting ship is included in the simulations, the spatiotemporal characteristics of the chorus change appreciably, in ways similar to changes observed during the experiment. [ABSTRACT FROM AUTHOR]

Published

2024

30. Multiple Sound Scattering by Combinations of Cylindrically Symmetric and Linearly Invariant Anomalies.

Author

Ivansson, Sven M.

Subjects

*SOUND wave scattering, *MULTIPLE scattering (Physics), *LINEAR equations, *PLANE wavefronts, *MODE-coupling theory (Phase transformations), *UNDERWATER acoustics, *ATMOSPHERIC acoustics, *HELMHOLTZ equation

Abstract

A number of previous papers have used the coupled-mode method to assess three-dimensional scattering by cylindrically symmetric anomalies (seamounts, hills) or anomalies which are invariant in a horizontal direction (wedges, ridges). This paper makes an extension to combinations of these two anomaly types. The upper and lower depth boundaries of the anomalies may be flat or irregular, and the sound source may be anywhere in the medium. After a discretization of the anomalies of the two types with laterally homogeneous rings and strips, respectively, an adaptation of the coupled-mode method yields the solution of the pertinent Helmholtz equation. The adaptation involves a combination of Fourier-series summations to handle the ring anomalies and adaptive wavenumber integrations to handle the strip structure. For each anomaly, recursively computed reflection matrices relate the expansion coefficients for incoming and outgoing normal modes. Iterative solution of a linear equation system for the amplitudes of the scattered cylindrical waves from the ring anomalies, involving formulas for transformation between plane and cylindrical waves, yields an expansion of the field. Related expansions allow isolation of partial waves, multiply scattered among the anomalies. The paper includes examples from underwater acoustics and atmospheric acoustics. [ABSTRACT FROM AUTHOR]

Published

2024

31. Tunable superior sound absorber design with nested hexagonal tracks.

Author

GAAFER, Fatma Nafaa

Subjects

*SUBMERGED structures, *UNDERWATER acoustics, *SOUND design, *ABSORPTION, *RESONANCE

Abstract

We propose a design of a tunable superior absorber based on the resonance absorption in underwater acoustic metastructure with nested hexagonal tracks. The structure comprises 37 hexagonal-shaped cells formed by two models depending on the formula for hexagonal numbers. Model I is labyrinthine acoustic metastructure (LAM), and model II is labyrinthine acoustic metastructure with a coil-up channel (LAMC). The results of model II demonstrate the achievement of a highly efficient sound absorber, with a maximum value of 0.999, within the frequency range of 130 Hz by rotating the third aperture at an angle of 180°. The effect of dissipative loss could be achieved by carefully controlling nested hexagonal tracks to achieve perfect absorption. Our research on tunable acoustic metastructure with absorbing properties has significant implications for engineering applications, particularly in noise mitigation. Our findings demonstrate the potential of these metastructures to provide tunable functionality, high efficiency, perfect absorption, and ease of construction, all within a compact design. [ABSTRACT FROM AUTHOR]

Published

2024

32. Feature Extraction Methods for Underwater Acoustic Target Recognition of Divers.

Author

Sun, Yuchen, Chen, Weiyi, Shuai, Changgeng, Zhang, Zhiqiang, Wang, Pingbo, Cheng, Guo, and Yu, Wenjing

Subjects

*FEATURE extraction, *SUPPORT vector machines, *DIVERS

Abstract

The extraction of typical features of underwater target signals and excellent recognition algorithms are the keys to achieving underwater acoustic target recognition of divers. This paper proposes a feature extraction method for diver signals: frequency−domain multi−sub−band energy (FMSE), aiming to achieve accurate recognition of diver underwater acoustic targets by passive sonar. The impact of the presence or absence of targets, different numbers of targets, different signal−to−noise ratios, and different detection distances on this method was studied based on experimental data under different conditions, such as water pools and lakes. It was found that the FMSE method has the best robustness and performance compared with two other signal feature extraction methods: mel frequency cepstral coefficient filtering and gammatone frequency cepstral coefficient filtering. Combined with the commonly used recognition algorithm of support vector machines, the FMSE method can achieve a comprehensive recognition accuracy of over 94% for frogman underwater acoustic targets. This indicates that the FMSE method is suitable for underwater acoustic recognition of diver targets. [ABSTRACT FROM AUTHOR]

Published

2024

33. Topology optimization of chiral metamaterials with application to underwater sound insulation.

Author

Wang, Chao, Zhao, Honggang, Wang, Yang, Zhong, Jie, Yu, Dianlong, and Wen, Jihong

Subjects

*UNDERWATER acoustics, *SOUNDPROOFING, *ACOUSTIC impedance, *POISSON'S ratio, *METAMATERIALS, *TRANSMISSION of sound

Abstract

Chiral metamaterials have been proven to possess many appealing mechanical phenomena, such as negative Poisson's ratio, high-impact resistance, and energy absorption. This work extends the applications of chiral metamaterials to underwater sound insulation. Various chiral metamaterials with low acoustic impedance and proper stiffness are inversely designed using the topology optimization scheme. Low acoustic impedance enables the metamaterials to have a high and broadband sound transmission loss (STL), while proper stiffness guarantees its robust acoustic performance under a hydrostatic pressure. As proof-of-concept demonstrations, two specimens are fabricated and tested in a water-filled impedance tube. Experimental results show that, on average, over 95% incident sound energy can be isolated by the specimens in a broad frequency range from 1 kHz to 5 kHz, while the sound insulation performance keeps stable under a certain hydrostatic pressure. This work may provide new insights for chiral metamaterials into the underwater applications with sound insulation. [ABSTRACT FROM AUTHOR]

Published

2024

34. Underwater vocalizations in foraging female Antarctic fur seals (Arctocephalus gazella) in the Kerguelen Islands.

Author

Chevallay, Mathilde, Guinet, Christophe, and Jeanniard du Dot, Tiphaine

Subjects

ANIMAL sound production, UNDERWATER acoustics, FUR, FORAGE fishes, STARTLE reaction, SOUND recordings, SIZE of fishes

Abstract

In the marine environment, many animals use sound to interact and communicate with their conspecifics or other species. Over the last decades, the development of sound recording systems has allowed a significant advance in our knowledge of sound production in marine animals. We deployed miniature sound and movement tags on Antarctic fur seals (AFS), a small otariid foraging on mesopelagic fish, to uncover potential underwater vocalizations in this species. Tags recorded underwater sounds synchronously with high‐resolution AFS movements and diving behavior, allowing us to investigate the behavioral context of vocalizations in the natural environment. We provide evidence of underwater vocalizations in foraging female AFS in a context of foraging at sea. AFS produced stereotyped calls made of low‐frequency pulses produced in series, exclusively during foraging dives. We hypothesized that these acoustic pulse series could be used as an acoustic lure to confuse or attract fish prey, however, a larger sample size is needed to study the adaptive significance of these underwater vocalizations. [ABSTRACT FROM AUTHOR]

Published

2024

35. Information geometry analysis example for absolute and relative transmission loss in a shallow ocean.

Author

Spendlove, Jay C., Neilsen, Tracianne B., and Transtrum, Mark K.

Subjects

UNDERWATER acoustics, ACOUSTIC measurements, GEOMETRIC analysis, MANIFOLDS (Mathematics), INFORMATION retrieval

Abstract

The model manifold, an information geometry tool, is a geometric representation of a model that can quantify the expected information content of modeling parameters. For a normal-mode sound propagation model in a shallow ocean environment, transmission loss (TL) is calculated for a vertical line array and model manifolds are constructed for both absolute and relative TL. For the example presented in this paper, relative TL yields more compact model manifolds with seabed environments that are less statistically distinguishable than manifolds of absolute TL. This example illustrates how model manifolds can be used to improve experimental design for inverse problems. [ABSTRACT FROM AUTHOR]

Published

2024

36. Passive Sonar Equation-Based Marine Mammal Detection Probability Modeling

Author

Menetrier, Baptiste, Pommier, Morgane, O’Brien, Joanne, Scholik-Schlomer, Amy R., Section editor, Popper, Arthur N., editor, Sisneros, Joseph A., editor, Hawkins, Anthony D., editor, and Thomsen, Frank, editor

Published

2024

37. Acoustic impacts of seismic surveys in complex underwater environments

Author

Jiménez Arranz, Guillermo, Blondel, Philippe, and Budd, Christopher

Subjects

underwater acoustics, seismic surveys, sound source verification, detection theory, airgun modelling, data processing, ABACUS, RAGAS

Abstract

The oil and gas industry employs powerful, low-frequency impulsive sources for exploration during seismic surveys. These sources, known as seismic air gun arrays, have the ability to propagate long distances. Seismic surveys can last for weeks and happen simultaneously at multiple locations around the world. These operations have the potential to disturb and displace marine mammals and other forms of marine life. There is a number of mitigation strategies that can be used to reduce the impact and exposure of marine animals to noise. For seismic surveys, the most cost-effective method consists in implementing a real-time monitoring plan around a predefined exclusion zone. If a marine mammal enters that area, the operations stop as requested by the Marine Mammal Observer (MMO) or Passive Acoustic Monitoring (PAM) technician who detected and identified the animal. Nowadays, these exclusion zones are calculated from sound field measurements or models, or a combination of both. For the purpose of sound source verification (SSV), a model of the sound field is required before the survey starts. The pre-survey simulation of the sound field is obtained as a combination of an air gun model, which simulates the acoustic output of the seismic source, and a propagation model, which simulates the pressure attenuation with distance. The pre-survey simulations are used to calculate the exclusion zone that is to be monitored before the sound mapping survey can gather the data necessary to verify the model. Once the data has been collected, a report is issued within 24-72 h. The report summarises the results of the model validation and provides an updated exclusion zone. In this context, there are three essential tools needed for noise impact assessment: a source model and propagation model for the pre-survey sound field simulations, and a software package that can generate a map of sound pressure levels from raw audio and position data. However, the tools currently available have some fundamental limitations: (1) commercial source models of air gun arrays are costly and are not designed for noise impact assessment, and (2) sound field processing is typically carried out with nonstandardised software routines developed by the companies providing the SSV services. In this thesis we present the design and implementation of two pieces of software: (1) a package for the computation of the sound field from raw audio and position data, and (2) a calibrated air gun array model that can compete with commercial software. The purpose of these tools is to provide efficient, accurate and free-access routines that can be used for the characterisation of the acoustic source, the sound field, and the propagation environment in the context of seismic surveys.

Published

2023

38. The accuracy of length measurements made using imaging SONAR is inversely proportional to the beamwidth

Author

Iain M. Parnum, Benjamin J. Saunders, Melanie Stott, Travis S. Elsdon, Michael J. Marnane, and Euan S. Harvey

Subjects

acoustic camera, imaging SONAR, underwater acoustics, underwater measurements, Ecology, QH540-549.5, Evolution, QH359-425

Abstract

Abstract Multibeam imaging SONARs have been used for a range of measurement applications, such as measurements of fish lengths. This study aimed to quantify the accuracy of imaging SONAR systems, that varied in frequency and beam geometry, to measure the length of synthetic targets positioned perpendicularly. Blueprint Oculus imaging SONAR systems, with four different (centre) frequencies (750 kHz, 1.2 MHz, 2.1 MHz and 3 MHz), were used to measure the length of three targets of nominal lengths: 10 cm, 20 cm and at ranges between 1 and 15.5 m. The effect of beam geometry on measurement error was then examined using regression analysis. This study found that there was an overestimation of the actual length of the target for all measurements that was inversely proportional to the horizontal beamwidth. The measurement error can be reduced by normalising for beamwidth. However, the variation of measurements (i.e. the precision) was found to also increase with range, which was attributed to the increasing beam separation. It is important that the effect of beamwidth on the accuracy of target length measurements, by imaging SONARs is acknowledged in future studies. One approach to mitigating this problem, is to limit the range at which length measurements are made to a beamwidth that produces an estimated level of error that is acceptable for that study.

Published

2024

39. Close listening.

Author

Gardiner, Bryan

Subjects

*UNDERWATER noise, *WHALING, *SOUND recordings, *UNDERWATER acoustics, *KILLER whale, *EAR, *ELEPHANTS, *INNER ear, *BATS

Abstract

Three books explore the wonders of sound in different contexts. "The Great Animal Orchestra" by Bernie Krause introduces the concept of "biophony," the collective sounds made by nonhuman organisms in a specific biome. Caspar Henderson's "A Book of Noises" adds the category of "cosmophony," or the sounds of the cosmos, to Krause's framework. Amorina Kingdon's "Sing Like Fish" focuses on the importance of sound in underwater life and the need for humans to pay attention to the impact of their own noise. Larry Sherman and Dennis Plies' "Every Brain Needs Music" delves into the neuroscience of making and listening to music. These books highlight the significance of sound in understanding and appreciating the world around us. [Extracted from the article]

Published

2024

40. Evaluation Method for Underwater Ultrasonic Energy Radiation Performance Based on the Spatial Distribution Characteristics of Acoustic Power.

Author

Liu, Zhongzheng, Zhang, Tao, Yuan, Yazhen, Li, Yuhang, and Geng, Yanzhang

Subjects

*ULTRASONIC waves, *UNDERWATER acoustics, *ACOUSTIC field, *ACOUSTIC radiation, *ACOUSTIC radiators, *ACOUSTIC wave propagation, *ULTRASONIC equipment

Abstract

In recent years, underwater wireless ultrasonic energy transmission technology (UWUET) has attracted much attention because it utilizes the propagation characteristics of ultrasound in water. Effectively evaluating the performance of underwater ultrasonic wireless energy transmission is a key issue in engineering design. The current approach to performance evaluation is usually based on the system energy transfer efficiency as the main criterion, but this criterion mainly considers the overall energy conversion efficiency between the transmitting end and the receiving end, without an in-depth analysis of the characteristics of the distribution of the underwater acoustic field and the energy loss that occurs during the propagation of acoustic waves. In addition, existing methods focusing on acoustic field analysis tend to concentrate on a single parameter, ignoring the dynamic distribution of acoustic energy in complex aquatic environments, as well as the effects of changes in the underwater environment on acoustic propagation, such as spatial variability in temperature and salinity. These limitations reduce the usefulness and accuracy of models in complex marine environments, which in turn reduces the efficiency of acoustic energy management and optimization. To solve these problems, this study proposes a method to evaluate the performance of underwater ultrasonic energy radiation based on the spatial distribution characteristics of acoustic power. By establishing an acoustic power distribution model in a complex impedance–density aqueous medium and combining numerical simulation and experimental validation, this paper explores the spatial variation of acoustic power and its impact on the energy transfer efficiency in depth. Using high-resolution spatial distribution data and actual environmental parameters, the method significantly improves the accuracy of the assessment and the adaptability of the model in complex underwater environments. The results show that, compared with the traditional method, this method performs better in terms of the accuracy of the acoustic energy radiation calculation results, and is able to reflect the energy distribution and spatial heterogeneity of the acoustic source more comprehensively, which provides an important theoretical basis and practical guidance for the optimal design and performance enhancement of the underwater ultrasonic wireless energy transmission system. [ABSTRACT FROM AUTHOR]

Published

2024

41. An Underwater Passive Electric Field Positioning Method Based on Scalar Potential.

Author

Zhang, Yi, Chen, Cong, Sun, Jiaqing, Qiu, Mingjie, and Wu, Xu

Subjects

*ELECTRIC fields, *DIFFERENTIAL evolution, *SUBMERSIBLES, *UNDERWATER acoustics, *SENSOR arrays, *MATHEMATICAL models

Abstract

In order to fulfill the practical application demands of precisely localizing underwater vehicles using passive electric field localization technology, we propose a scalar-potential-based method for the passive electric field localization of underwater vehicles. This method is grounded on an intelligent differential evolution algorithm and is particularly suited for use in three-layer and stratified oceanic environments. Firstly, based on the potential distribution law of constant current elements in a three-layer parallel stratified ocean environment, the mathematical positioning model is established using the mirror method. Secondly, the differential evolution (DE) algorithm is enhanced with a parameter-adaptive strategy and a boundary mutation processing mechanism to optimize the key objective function in the positioning problem. Additionally, the simulation experiments of the current element in the layered model prove the effectiveness of the proposed positioning method and show that it has no special requirements for the sensor measurement array, but the large range and moderate number of sensors are beneficial to improve the positioning effect. Finally, the laboratory experiments on the positioning method proposed in this paper, involving underwater simulated current elements and underwater vehicle tracks, were carried out successfully. The results indicate that the positioning method proposed in this paper can achieve the performance requirements of independent initial value, strong anti-noise capabilities, rapid positioning speed, easy implementation, and suitability in shallow sea environments. These findings suggest a promising practical application potential for the proposed method. [ABSTRACT FROM AUTHOR]

Published

2024

42. Mechanoluminescence and Mechanical Quenching of Afterglow Luminescent Particles for Wearable Photonic Display.

Author

Kim, Seong‐Jong, Yang, Fan, Jung, Ho Sang, Hong, Guosong, and Hahn, Sei Kwang

Subjects

*DISPLAY systems, *TELECOMMUNICATION systems, *BIOMEDICAL materials, *OPTICAL properties, *UNDERWATER acoustics

Abstract

Optical properties of afterglow luminescent particles (ALPs) in mechanoluminescence (ML) and mechanical quenching (MQ) have attracted great attention for diverse technological applications. However, these unique phenomena need to be more clearly explained for the specific photonic application. Here, ALPs are designed for the development of a wearable and rewritable photonic display system as a communication toolbox under dark conditions or underwater environments with limited communication. This display system demonstrates long‐lasting MQ after short ML along the handwritten trajectories with mechanical pressure and the written content can be easily erased by short UV light irradiation, preserving the system integrity with the high reproducibility of ML and MQ responses. The effect of trapped electrons and the recharging process on the ML and MQ is assessed, which provides insights into their underlying mechanisms. In addition, this display system exhibits remarkable resistance to humidity and retains its rewritable and photonic capabilities underwater for a long‐term period. Furthermore, the rewritable property of display system on human skin is demonstrated, confirming their effectiveness as a wearable photonic display system. Taken together, this research will pave a big new avenue to develop biophotonic materials for various biomedical applications with mechano‐optical conversions. [ABSTRACT FROM AUTHOR]

Published

2024

43. On the Accuracy of Distance Estimates Based on Sound Signal Propagation Time on the Arctic Shelf.

Author

Nazarenko, Yu. V., Sidorov, D. D., Petnikov, V. G., Pisarev, S. V., and Lunkov, A. A.

Subjects

*SHALLOW water acoustics, *SPEED of sound, *UNDERWATER acoustics, *UNDERWATER navigation, *ACOUSTIC wave propagation

Abstract

Applying numerical modelling approach the accuracy in determining the distance between underwater sound sources and receivers is assessed at a range of several kilometers from each other in the Kara Sea in autumn. It is suggested that the main source of errors in determining the distance is the lack of accurate data on the vertical sound speed profile along the acoustic signal propagation path. Data from September and November were analyzed, in the interval between which significant changes in the profile take place, when the vertical sound speed gradient changes from negative to positive. Characteristic values of sound speed variations were obtained by statistical processing of hydrological data taken from the World Ocean Database. The results are important for analyzing the capabilities of underwater acoustic navigation. [ABSTRACT FROM AUTHOR]

Published

2024

44. Holographic Method for Localizing an Underwater Noise Source in a Shallow Sea.

Author

Glushchenko, M. Yu., Kuz'kin, V. M., Matvienko, Yu. V., Pereselkov, S. A., Khvorostov, Yu. A., and Tkachenko, S. A.

Subjects

*UNDERWATER noise, *UNDERWATER acoustics, *SIGNAL-to-noise ratio, *WATER depth, *SEAWATER

Abstract

The article presents the results of a high-frequency experiment to detect and determine the bearing of a small-sized underwater noise sound source, carried out in shallow waters of the Black Sea coast. Noise emission from the source was received by three single vector–scalar receivers located at the bottom. Holographic processing was used to detect and determine the bearing of a moving underwater source against a background of heavy shipping in the water area of the experiment. Estimates of the input signal/noise ratio are given. [ABSTRACT FROM AUTHOR]

Published

2024

45. Extracting dolphin whistles in complex acoustic scenarios: a case study in the Bay of Biscay.

Author

Miralles, Ramón, Gallardo, Carles, Lara, Guillermo, and Bou Cabo, Manuel

Subjects

*BOTTLENOSE dolphin, *DOLPHINS, *WHISTLES, *DATABASES, *UNDERWATER acoustics, *TIME-frequency analysis

Abstract

Accurate whistle contour extraction is crucial in many dolphin behavioural studies. Traditionally, whistle contour extraction involves a first step of finding whistle candidates by peak-level detection in the time-frequency domain, followed by a determination of when peaks are close enough to each other to be part of the same whistle contour. In complex scenarios, such as those with a large number of individuals vocalising simultaneously or those with a sudden increase in background noise, peak-level detection may not provide a number of accurate whistle candidates that is large enough to extract the whistle contour or to disambiguate individual whistles when they cross one another. In these adverse scenarios, a different approach, based on the pyknogram representation, can produce a more accurate detection of whistle candidates and evenly distributed candidates throughout the duration of the whistle. This work compares the peak-level extraction approach of the spectrogram with the point-density extraction approach of the pyknogram. We propose a technique that combines estimates of the central frequency and bandwidth to extract whistle candidates in adverse scenarios. The method has been successfully used for the vocalisation extraction of dolphins in the Bay of Biscay (Spain) using a database of more than 2000 dolphin whistles. [ABSTRACT FROM AUTHOR]

Published

2024

46. Reliable Pilot Search Method for Enhancing BER Performance in Underwater Acoustic OFDM Systems with MMSE Estimator.

Author

Nguyen, Thi Nga, Phan, Anh Huy, Cao, Van Loi, and Hiep, Pham Thanh

Subjects

*CHANNEL estimation, *BIT error rate, *MINI-Mental State Examination, *UNDERWATER acoustics, *IMPULSE response, *DATA transmission systems

Abstract

A small set of pilots in underwater acoustics OFDM (UWA-OFDM) systems tends to be insufficient for recovering the channel impulse response (CIR). This may result from the fast changes in the propagation environment and the requirement for high transmission data rates. A previous work, namely PE, considered the received subcarriers whose distances to their closest constellation points below the predetermined threshold T as potential pilots. However, extracting these pilots at the same time gives no chance to use some of them to facilitate searching for others. Fixing threshold T is also another limitation for searching pilot candidates. This paper proposes a reliable pilot search (RPS) method that consists of a multi-iterations pilot searching process with an adaptive threshold T a to improve the estimator in UWA-OFDM. The pilot search process gradually extracts reliable pilots at each iteration based on the threshold T a and evaluates them by performing channel estimation. Our method is compared to the MMSE and PE estimators on a wide range of settings, including the number of channel taps, pilot spacing, and various modulation schemes (i.e., MPSK and MQAM). The experimental results show that the RPS method often outperforms the MMSE and PE methods in terms of bit error rate (BER). [ABSTRACT FROM AUTHOR]

Published

2024

47. Whistles in the Vocal Repertoire of Bottlenose Dolphins (Tursiops truncatus Montagu, 1821) and Common Dolphins (Delphinus delphis Linnaeus, 1758).

Author

Agafonov, A. V., Melnikova, P. K., Panova, E. M., Logominova, I. V., and Litvin, V. A.

Subjects

*BOTTLENOSE dolphin, *DOLPHINS, *WHISTLES, *UNDERWATER acoustics, *NUMBERS of species

Abstract

The article performs a comparative analysis of the underwater sounds of two sympatric dolphin species living in the Black Sea: bottlenose and common dolphins. During sound processing and analysis, the special program nanoCAD 22 was used. Both the similarity of the physical parameters of the sounds of the two species and a number of specific features of whistles characteristic of each were demonstrated. Common dolphin production of some types of whistles with significant similarities (sometimes almost identical) to the signature whistles of bottlenose dolphins was detected and analyzed. [ABSTRACT FROM AUTHOR]

Published

2024

48. Heard off Heard: Acoustic detections of sperm whales (Physeter macrocephalus) and other cetaceans off Heard Island.

Author

Miller, Brian S., Masere, Cara, Milnes, Mark, Cleeland, Jaimie, Lamb, Timothy, Maschette, Dale, and Welsford, Dirk

Subjects

SPERM whale, UNDERWATER acoustics, TOOTHED whales, DEMOGRAPHY

Abstract

An underwater acoustic recorder was moored off Heard Island from September 2017 through March 2018 to listen for marine mammals. Analysis of data was initially conducted by visual inspection of long-term spectral averages to reveal sounds from sperm whales, Antarctic and pygmy blue whales, fin whales, minke whales, odontocete whistles, and noise from nearby ships. Automated detection of sperm whale clicks revealed they were seldom detected from September through January (n = 35 h) but were detected nearly every day of February and March (n = 684 h). Additional analysis of these detections revealed further diel and demographic patterns. [ABSTRACT FROM AUTHOR]

Published

2024

49. Adaptive interference suppression based on an invariant subspace of matrices matching for a horizontal array in underwater acoustics.

Author

Sheng, Xueli, Li, Dewen, Cao, Ran, Zhou, Xuan, and Yin, Jiarui

Subjects

UNDERWATER acoustics, EIGENVECTORS, INTERFERENCE (Sound), INVARIANT subspaces, COVARIANCE matrices

Abstract

Passive detection of target-of-interest (TOI) within strong interferences poses a challenge. This paper introduces an adaptive interference suppression based on an invariant subspace of matrix matching. Assume that the TOI-bearing intervals are known. We define a correlation ratio for each eigenvector to obtain the highest one. Then, we use invariant subspace of matrix matching to measure the distance between two invariant projection matrices of this eigenvector. This identifies and removes the eigenvectors associated with TOI. Finally, the remaining eigenvectors are subtracted from the sample covariance matrix to suppress interference and noise. The viability of the proposed method is demonstrated experimentally. [ABSTRACT FROM AUTHOR]

Published

2024

50. Underwater Coherent Source Direction-of-Arrival Estimation Method Based on PGR-SubspaceNet.

Author

Guo, Tuo, Xu, Yunyan, Bi, Yang, Ding, Shaochun, and Huang, Yong

Subjects

DIRECTION of arrival estimation, UNDERWATER acoustics, SIGNAL-to-noise ratio, STANDARD deviations, COMPLEX variables

Abstract

In the field of underwater acoustics, the signal-to-noise ratio (SNR) is generally low, and the underwater environment is complex and variable, making target azimuth estimation highly challenging. Traditional model-based subspace methods exhibit significant performance degradation when dealing with coherent sources, low SNR, and small snapshot data. To overcome these limitations, an improved model based on SubspaceNet, called PConv-GAM Residual SubspaceNet (PGR-SubspaceNet), is proposed. This model embeds the global attention mechanism (GAM) into residual blocks that fuse PConv convolution, making it possible to capture richer cross-channel and positional information. This enhancement helps the model learn signal features in complex underwater conditions. Simulation results demonstrate that the underwater target azimuth estimation method based on PGR-SubspaceNet exhibits lower root mean square periodic error (RMSPE) values when handling different numbers of narrowband coherent sources. Under low SNR and limited snapshot conditions, its RMSPE values are significantly better than those of traditional methods and SubspaceNet-based enhanced subspace methods. PGR-SubspaceNet extracts more features, further improving the accuracy of direction-of-arrival estimation. Preliminary experiments in a pool validate the effectiveness and feasibility of the underwater target azimuth estimation method based on PGR-SubspaceNet. [ABSTRACT FROM AUTHOR]

Published

2024