Your search keyword '"Acoustic transmission"' showing total 326 results

1. The Impact of Special Marine Environments Such as the Kuroshio on Hydroacoustic Detection Equipment.

Author

Zhang, Xueqin, Yang, Kunde, and Yu, Xiaolin

Subjects

SEAMOUNTS, DEPTH sounding, KUROSHIO, ACOUSTIC wave propagation, TOPOGRAPHY

Abstract

In order to study the impact of acoustic propagation characteristics in the northeastern South China Sea, GEBCO08 global terrain grid data and Argo data were used to numerically simulate the acoustic transmission characteristics of two stations in the northeast South China Sea affected by the Kuroshio. The impact of different marine environments on acoustic transmission characteristics was analyzed. The results show that increasing the deployment depth of a sound source within a certain range will reduce the transmission loss; deploying a sound source near the axis of the surface acoustic channel or the deep-sea acoustic channel will also greatly increase the propagation distance of sound signals; and the presence of topography such as undersea mountains will increase the transmission loss. [ABSTRACT FROM AUTHOR]

Published

2024

2. Acoustic Transmission Measurements for Extracting the Mechanical Properties of Complex 3D MEMS Transducers.

Author

Becker, Dennis, Littwin, Moritz, Bittner, Achim, and Dehé, Alfons

Subjects

ACOUSTIC transducers, ACOUSTIC measurements, TRANSDUCERS, COMPUTER simulation, MEASUREMENT

Abstract

Recent publications on acoustic MEMS transducers present a new three-dimensional folded diaphragm that utilizes buried in-plane vibrating structures to increase the active area from a small chip volume. Characterization of the mechanical properties plays a key role in the development of new MEMS transducers, whereby established measurement methods are usually tailored to structures close to the sample surface. In order to access the lateral vibrations, extensive and destructive sample preparation is required. This work presents a new passive measurement technique that combines acoustic transmission measurements and lumped-element modelling. For diaphragms of different lengths, compliances between 0.08 × 10−15 and 1.04 × 10−15 m3/Pa are determined without using destructive or complex preparations. In particular, for lengths above 1000 µm, the results differ from numerical simulations by only 4% or less. [ABSTRACT FROM AUTHOR]

Published

2024

3. Numerical and Experimental Investigations on the Acoustic Characteristics of a Single-Stage Centrifugal Pump †.

Author

Lehr, Christian, Munsch, Pascal, Skoda, Romuald, and Brümmer, Andreas

Subjects

CENTRIFUGAL pumps, ACOUSTIC excitation, FLUID-structure interaction, ACOUSTIC impedance, FLOW separation, SURFACE roughness

Abstract

The acoustic properties of a single-stage centrifugal pump with low specific speed are investigated by means of compressible 3D CFD simulations (URANS) and experiments. In order to determine the pump's acoustic transmission and excitation characteristics, a four-pole approach in the frequency domain is used. The transmission parameters determined by simulation are compared to experiments in water and air as functions of the Helmholtz number. The results indicate that the acoustic transmission characteristics within the experiments are significantly influenced by the structural compliance of the volute casing in terms of a fluid–structure interaction (FSI). A modelling approach for a one-dimensional representation of the centrifugal pump's acoustic transmission characteristics in the time and frequency domains is applied to the current pump. As one model parameter, the effective speed of sound in the 1D model needs to be reduced to 607 m s − 1 to account for the FSI. The agreement of the simulation results and the experiments underlines the above statement about the influence of the FSI. In a last step, the acoustic excitation parameter, depicted as monopole and dipole amplitudes, at two different blade-passing frequencies ( f B P ≈ [ 111 ; 169 ] Hz) are determined for several operating points. Especially for dipole amplitudes, a good agreement between experiments and simulations can be seen. The monopole amplitudes are also of similar orders of magnitude, but show stronger deviations. The cause of discrepancies between the 3D CFD simulations and experiments is believed to be the neglected influence of the FSI and surface roughness as well as the inaccurate reproduction of flow separation at the volute's tongue due to the use of wall functions. A final important observation made during the numerical investigations is that the excitation mechanisms at the blade-passing frequency are probably independent of the piping system's acoustic impedance. [ABSTRACT FROM AUTHOR]

Published

2024

4. The Impact of Special Marine Environments Such as the Kuroshio on Hydroacoustic Detection Equipment

Author

Xueqin Zhang, Kunde Yang, and Xiaolin Yu

Subjects

marine environments, acoustic transmission, topography, Naval architecture. Shipbuilding. Marine engineering, VM1-989, Oceanography, GC1-1581

Abstract

In order to study the impact of acoustic propagation characteristics in the northeastern South China Sea, GEBCO08 global terrain grid data and Argo data were used to numerically simulate the acoustic transmission characteristics of two stations in the northeast South China Sea affected by the Kuroshio. The impact of different marine environments on acoustic transmission characteristics was analyzed. The results show that increasing the deployment depth of a sound source within a certain range will reduce the transmission loss; deploying a sound source near the axis of the surface acoustic channel or the deep-sea acoustic channel will also greatly increase the propagation distance of sound signals; and the presence of topography such as undersea mountains will increase the transmission loss.

Published

2024

5. Acoustic Transmission Measurements for Extracting the Mechanical Properties of Complex 3D MEMS Transducers

Author

Dennis Becker, Moritz Littwin, Achim Bittner, and Alfons Dehé

Subjects

acoustic transmission, characterization, MEMS transducer, modeling, folded diaphragm, Mechanical engineering and machinery, TJ1-1570

Abstract

Recent publications on acoustic MEMS transducers present a new three-dimensional folded diaphragm that utilizes buried in-plane vibrating structures to increase the active area from a small chip volume. Characterization of the mechanical properties plays a key role in the development of new MEMS transducers, whereby established measurement methods are usually tailored to structures close to the sample surface. In order to access the lateral vibrations, extensive and destructive sample preparation is required. This work presents a new passive measurement technique that combines acoustic transmission measurements and lumped-element modelling. For diaphragms of different lengths, compliances between 0.08 × 10−15 and 1.04 × 10−15 m3/Pa are determined without using destructive or complex preparations. In particular, for lengths above 1000 µm, the results differ from numerical simulations by only 4% or less.

Published

2024

6. FEM Investigation of a Multi-Neck Helmholtz Resonator.

Author

Papadakis, Nikolaos M. and Stavroulakis, Georgios E.

Subjects

HELMHOLTZ resonators, MUSICAL acoustics & physics, LUMPED elements, FINITE element method, ACOUSTIC field

Abstract

An increasingly significant area of research with several applications in numerous disciplines is that of multi-neck Helmholtz resonators. This research is set to explore the accuracy and applicability of the finite element method (FEM) for the calculation of the resonance frequency of multi-neck Helmholtz resonators. The FEM is employed for the estimation of the resonance frequency in various cases of multi-neck Helmholtz resonators: with cylindrical or spherical bodies, with unflanged or flanged necks of various dimensions and with various combinations of the above. Also, single neck resonators are examined. The FEM results are compared with the results of a recently proposed theoretical model available in the literature and with the outcome of the lumped element approximation (multi-neck) accounting for the added neck surface area. Comparisons revealed little deviation between the FEM and theoretical model (less than 1.1% error of calculation for every case). On the contrary, in comparison with the lumped element approximation (multi-neck), the error of calculation is significant (up to 40.3% for the cases examined). The FEM will prove useful in expanding our understanding of how multi-neck Helmholtz resonators perform under various conditions and configurations. The present research, which highlights the applicability of the FEM for the calculations of the resonance frequency of multi-neck Helmholtz resonators, goes a step further; this approach can be applied in special cases where it is not trivial to apply an analytical formula. The method can be used for applications of multi-neck Helmholtz resonators for various fields such as acoustic metamaterials, musical acoustics and noise mitigation. [ABSTRACT FROM AUTHOR]

Published

2023

7. Tunable Helmholtz Resonators Using Multiple Necks.

Author

Papadakis, Nikolaos M. and Stavroulakis, Georgios E.

Subjects

HELMHOLTZ resonators, ACOUSTIC resonance, ARCHITECTURAL acoustics, FINITE element method, STRINGED instruments, ACOUSTICAL materials

Abstract

One of the uses of Helmholtz resonators is as sound absorbers for room acoustic applications, especially for the low frequency range. Their efficiency is centered around their resonance frequency which mainly depends on elements of their geometry such as the resonator volume and neck dimensions. Incorporating additional necks on the body of a Helmholtz resonator (depending on whether they are open or closed) has been found to alter the resulting resonance frequency. For this study, tunable Helmholtz resonators to multiple resonance frequencies, are proposed and investigated utilizing additional necks. The resonance frequencies of various multi-neck Helmholtz resonators are first modeled with the use of the finite element method (FEM), then calculated with the use of an analytical approach and the results of the two approaches are finally compared. The results of this study show that Helmholtz resonators with multiple resonances at desired frequencies are achievable with the use of additional necks, while FEM and analytical methods can be used for the estimation of the resonance frequencies. Analytical and FEM approach results show a good agreement in cases of small number of additional necks, while the increasing differences in cases of higher neck additions, were attributed to the change in effective length of the necks as demonstrated by FEM. The proposed approach can be useful for tunable sound absorbers for room acoustics applications according to the needs of a space. Also, this approach can be applied in cases of additional tunable air resonances of acoustic instruments (e.g., string instruments). [ABSTRACT FROM AUTHOR]

Published

2023

8. Bandgap optimization for chiral acoustic metamaterials based on material selection method

Author

Luyun CHEN and Xing XIE

Subjects

acoustic metamaterials, material selection, bandgaps optimization, normalizing, acoustic transmission, Naval architecture. Shipbuilding. Marine engineering, VM1-989

Abstract

ObjectivesThis study seeks to expand the bandgap frequency band, reduce the bandgap starting frequency and analyze and optimize the bandgap parameters of acoustic metamaterials. MethodsThe influence of geometrical and material parameters on the bandgap properties of acoustic metamaterials is analyzed, and a method for maximizing the bandgap width is proposed. The multi-objective optimization problem is converted into a single objective optimization problem by normalizing the bandgap frequency coefficients. Structural material conversion is achieved via the material selection optimization method, and the optimization equations of bandgap parameters are established on the basis of weight-lightening. For chiral acoustic metamaterials, the material properties (density and wave velocity) and geometric parameters (scatterer diameter, ligament thickness and coating thickness) are defined as design variables, and the comprehensive optimization of structural parameters and material selection of acoustic metamaterials based on weight-lightening are implemented. ResultsThe optimization results show that the bandgap width increases by 27.7% and the lower bound frequency decreases by 1048 Hz, thereby achieving the goal of expanding the bandgap width based on lightweight acoustic metamaterials. The acoustic transmission analysis of the finite chiral acoustic metamaterial structure is then carried out to verify the effectiveness of the proposed method. ConclusionsThe results show that the goal of lightweight acoustic metamaterials can be effectively achieved by integrating the comprehensive optimization of structural parameters and materials. As such, this study provides references for the design of new-type acoustic metamaterials.

Published

2023

9. Numerical and Experimental Investigations on the Acoustic Characteristics of a Single-Stage Centrifugal Pump

Author

Christian Lehr, Pascal Munsch, Romuald Skoda, and Andreas Brümmer

Subjects

centrifugal pump, acoustic transmission, acoustic excitation, fluid–structure interaction (FSI), rotor–stator interaction (RSI), hydro-acoustic, Mechanical engineering and machinery, TJ1-1570

Abstract

The acoustic properties of a single-stage centrifugal pump with low specific speed are investigated by means of compressible 3D CFD simulations (URANS) and experiments. In order to determine the pump’s acoustic transmission and excitation characteristics, a four-pole approach in the frequency domain is used. The transmission parameters determined by simulation are compared to experiments in water and air as functions of the Helmholtz number. The results indicate that the acoustic transmission characteristics within the experiments are significantly influenced by the structural compliance of the volute casing in terms of a fluid–structure interaction (FSI). A modelling approach for a one-dimensional representation of the centrifugal pump’s acoustic transmission characteristics in the time and frequency domains is applied to the current pump. As one model parameter, the effective speed of sound in the 1D model needs to be reduced to 607 ms−1 to account for the FSI. The agreement of the simulation results and the experiments underlines the above statement about the influence of the FSI. In a last step, the acoustic excitation parameter, depicted as monopole and dipole amplitudes, at two different blade-passing frequencies (fBP≈[111;169] Hz) are determined for several operating points. Especially for dipole amplitudes, a good agreement between experiments and simulations can be seen. The monopole amplitudes are also of similar orders of magnitude, but show stronger deviations. The cause of discrepancies between the 3D CFD simulations and experiments is believed to be the neglected influence of the FSI and surface roughness as well as the inaccurate reproduction of flow separation at the volute’s tongue due to the use of wall functions. A final important observation made during the numerical investigations is that the excitation mechanisms at the blade-passing frequency are probably independent of the piping system’s acoustic impedance.

Published

2024

10. FEM Investigation of a Multi-Neck Helmholtz Resonator

Author

Nikolaos M. Papadakis and Georgios E. Stavroulakis

Subjects

Helmholtz resonator, multi-neck Helmholtz resonator, finite element method, leakage, absorption, acoustic transmission, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

An increasingly significant area of research with several applications in numerous disciplines is that of multi-neck Helmholtz resonators. This research is set to explore the accuracy and applicability of the finite element method (FEM) for the calculation of the resonance frequency of multi-neck Helmholtz resonators. The FEM is employed for the estimation of the resonance frequency in various cases of multi-neck Helmholtz resonators: with cylindrical or spherical bodies, with unflanged or flanged necks of various dimensions and with various combinations of the above. Also, single neck resonators are examined. The FEM results are compared with the results of a recently proposed theoretical model available in the literature and with the outcome of the lumped element approximation (multi-neck) accounting for the added neck surface area. Comparisons revealed little deviation between the FEM and theoretical model (less than 1.1% error of calculation for every case). On the contrary, in comparison with the lumped element approximation (multi-neck), the error of calculation is significant (up to 40.3% for the cases examined). The FEM will prove useful in expanding our understanding of how multi-neck Helmholtz resonators perform under various conditions and configurations. The present research, which highlights the applicability of the FEM for the calculations of the resonance frequency of multi-neck Helmholtz resonators, goes a step further; this approach can be applied in special cases where it is not trivial to apply an analytical formula. The method can be used for applications of multi-neck Helmholtz resonators for various fields such as acoustic metamaterials, musical acoustics and noise mitigation.

Published

2023

11. Leakage Effect on the Transmission Properties of a Duct Loaded with a Helmholtz Resonator.

Author

Ou, Yang and Zhao, Yonghui

Subjects

HELMHOLTZ resonators, LEAK detection, LEAKAGE, ACOUSTIC field, RESONANCE

Abstract

The characteristics of transmitted acoustic field have important significance to the leakage detection and the acoustic metasurface technology. When the additional leak holes are present, the conventional single neck Helmholtz resonator will naturally become the one with multiple necks. Based on such a background, in this paper, the effects of leakages on the transmission properties of a Duct Helmholtz Resonator (DHR) device is investigated both analytically and numerically. A set of closed-form formulas are derived to analytically predict the transmission spectra of the DHR device with leakages. The theoretical results are compared with COMSOL predictions. The simulation results show that the number and width of leak holes have significant influences on the amplitude, phase shift of the transmitted wave, and resonance frequency of the DHR system. [ABSTRACT FROM AUTHOR]

Published

2022

12. Design, characterization and evaluation of a laser-guided focused ultrasound system for preclinical investigations

Author

Pavlos Anastasiadis, Ali Mohammadabadi, Meyer J. Fishman, Jesse A. Smith, Ben A. Nguyen, David S. Hersh, and Victor Frenkel

Subjects

Focused ultrasound, Laser targeting, Simulations, Hydrophone measurements, Hydrogel phantoms, Acoustic transmission, Medical technology, R855-855.5

Abstract

Abstract Background The clinical applications of transcranial focused ultrasound continue to expand and include ablation as well as drug delivery applications in the brain, where treatments are typically guided by MRI. Although MRI-guided focused ultrasound systems are also preferred for many preclinical investigations, they are expensive to purchase and operate, and require the presence of a nearby imaging center. For many basic mechanistic studies, however, MRI is not required. The purpose of this study was to design, construct, characterize and evaluate a portable, custom, laser-guided focused ultrasound system for noninvasive, transcranial treatments in small rodents. Methods The system comprised an off-the-shelf focused ultrasound transducer and amplifier, with a custom cone fabricated for direct coupling of the transducer to the head region. A laser-guidance apparatus was constructed with a 3D stage for accurate positioning to 1 mm. Pressure field simulations were performed to demonstrate the effects of the coupling cone and the sealing membrane, as well as for determining the location of the focus and acoustic transmission across rat skulls over a range of sizes. Hydrophone measurements and exposures in hydrogels were used to assess the accuracy of the simulations. In vivo treatments were performed in rodents for opening the blood–brain barrier and to assess the performance and accuracy of the system. The effects of varying the acoustic pressure, microbubble dose and animal size were evaluated in terms of efficacy and safety of the treatments. Results The simulation results were validated by the hydrophone measurements and exposures in the hydrogels. The in vivo treatments demonstrated the ability of the system to open the blood–brain barrier. A higher acoustic pressure was required in larger-sized animals, as predicted by the simulations and transmission measurements. In a particular sized animal, the degree of blood–brain barrier opening, and the safety of the treatments were directly associated with the microbubble dose. Conclusion The focused ultrasound system that was developed was found to be a cost-effective alternative to MRI-guided systems as an investigational device that is capable of accurately providing noninvasive, transcranial treatments in rodents.

Published

2019

13. Leakage Effect on the Transmission Properties of a Duct Loaded with a Helmholtz Resonator

Author

Yang Ou and Yonghui Zhao

Subjects

Duct-Helmholtz-Resonator, leakage, acoustic transmission, multi-neck Helmholtz resonator, closed-form formulas, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

The characteristics of transmitted acoustic field have important significance to the leakage detection and the acoustic metasurface technology. When the additional leak holes are present, the conventional single neck Helmholtz resonator will naturally become the one with multiple necks. Based on such a background, in this paper, the effects of leakages on the transmission properties of a Duct Helmholtz Resonator (DHR) device is investigated both analytically and numerically. A set of closed-form formulas are derived to analytically predict the transmission spectra of the DHR device with leakages. The theoretical results are compared with COMSOL predictions. The simulation results show that the number and width of leak holes have significant influences on the amplitude, phase shift of the transmitted wave, and resonance frequency of the DHR system.

Published

2022

14. High and dry: Trade-off in arboreal calling in a treefrog mediated by local environment.

Author

Cicchino, Amanda S, Cairns, Nicholas A, Bulté, Grégory, and Lougheed, Stephen C

Subjects

*GROUND vegetation cover, *TRANSMISSION of sound, *TELEPHONE calls

Abstract

Trade-offs shaping behavioral variation are often influenced by the environment. We investigated the role that the environment plays in mediating trade-offs using a widespread frog with a conspicuous mating display, Pseudacris crucifer. We first demonstrated, using playback and desiccation experiments, that calling site selection involves a trade-off between sound transmission and desiccation. We then determined the influence of local environmental conditions on the intensity of the trade-off by examining range-wide behavioral and environmental data. We showed that the benefit of improved call transmission is positively influenced by vegetation density and ground cover. Behavioral data are consistent with this relationship: sites with a greater transmission benefit have increased prevalence of arboreally calling males. We also found that the prevalence of arboreal calling behavior increases with relative humidity and air temperature, suggesting an influence of these environmental variables on the desiccation cost of arboreal calling. This study provides a clear example of the role of the environment in mediating trade-off intensities and shaping critical behavioral traits. Local environment mediates the intensity of a trade-off associated with arboreal calling behavior in a treefrog. Combining observational and experimental approaches, we show that arboreal calling behavior increases the transmission of a mating call while potentially subjecting individuals to a rate of desiccation six times greater than terrestrial calling. Local environmental conditions influence both the benefit and the cost of this trade-off, subjecting different populations to varying trade-off intensities and shaping arboreal calling behavior. [ABSTRACT FROM AUTHOR]

Published

2020

15. Sound and vibration transmission in aircraft using statistical energy analysis

Author

Platten, Michael Francis

Subjects

534, Fuselage, acoustic transmission

Published

1998

16. Simulations and Experimental Investigations on the Acoustic Characterization of Centrifugal Pumps of Different Specific Speed.

Author

Lehr, Christian, Linkamp, Andreas, Aurich, Daniel, and Brümmer, Andreas

Subjects

CENTRIFUGAL pumps, ACOUSTIC field, COMPUTER simulation, SCATTERING parameters (Computer networks), NUMERICAL analysis

Abstract

Subject of discussion are simulations and experimental investigations on the acoustic characterization of three single stage centrifugal pumps of different specific speed. In operation, these pump-types generate pressure pulsation at blade passing frequency, primarily due to rotor-volute-interaction. In order to determine the acoustic excitation it is necessary to know about the pumps' acoustic transmission parameters. In this paper, a one-dimensional numerical model for transient time-domain simulation is presented, which takes into account the pump geometry as well as the volutes' structural behaviour by means of the local effective speed of sound. Numerical results for the transmission characteristics of the three different pumps are shown in terms of scattering matrices and evaluated against parameters calculated from measurement results. The experimental analyses are carried out using dynamic pressure sensors in both the suction and the discharge pipe. Assuming solely plane wave propagation, the complex acoustic field on each side is evaluated independently. The so called "two source" method is then used to determine the transmission parameters of the pumps in standstill for a range of frequencies experimentally. Subsequently, the acoustic excitation at varying rotational speed is evaluated by means of measurements at the pumps in operation and presented as monopole and dipole source types for cavitation-free conditions. [ABSTRACT FROM AUTHOR]

Published

2019

17. Transferring Data from Smartwatch to Smartphone through Mechanical Wave Propagation

Author

Seung-Chan Kim and Soo-Chul Lim

Subjects

ultrasonic, acoustic transmission, non-radio communication, intra-body propagation, inter-device communication, Chemical technology, TP1-1185

Abstract

Inspired by the mechanisms of bone conduction transmission, we present a novel sensor and actuation system that enables a smartwatch to securely communicate with a peripheral touch device, such as a smartphone. Our system regards hand structures as a mechanical waveguide that transmits particular signals through mechanical waves. As a signal, we used high-frequency vibrations (18.0–20.0 kHz) so that users cannot sense the signals either tactually or audibly. To this end, we adopted a commercial surface transducer, which is originally developed as a bone-conduction actuator, for mechanical signal generation. At the receiver side, a piezoelement was adopted for picking up the transferred mechanical signals. Experimental results have shown that the proposed system can successfully transfer data using mechanical waves. We also validate dual-frequency actuations under which high-frequency signals (18.0–20.0 kHz) are generated along with low-frequency (up to 250 Hz) haptic vibrations. The proposed method has advantages in terms of security in that it does not reveal the signals outside the body, meaning that it is not possible for attackers to eavesdrop on the signals. To further illustrate the possible application spaces, we conclude with explorations of the proposed approach.

Published

2015

18. The effect of nature of porous material on diffuse field acoustic transmission of the sandwich aerospace composite doubly curved shell.

Author

Talebitooti, R. and Zarastvand, M.R.

Subjects

*ACOUSTIC field, *THEORY of wave motion, *POROELASTICITY, *TRANSMISSION of sound, *POROUS materials

Abstract

This paper investigates a diffuse acoustic field to analyze the wave propagation on infinite doubly curved laminated composite shell sandwiching a porous material which is extensively used in aerospace structures. In fact, the main goal is to study the influence of embedded porous core on Sound Transmission Loss (STL) of the structure. Accordingly, Biot's theory is employed to model the poroelastic material which considers three types of wave propagation including two compression and one shear terms. In addition, Shear Deformation Shallow Shell Theory (SDSST) is applied to derive the wave propagation through double-walled laminated composite shell. Moreover, a numerical process is prepared to investigate a random incidence STL in a diffuse acoustic field which results in presenting the Limiting angle of incidence in which no incident wave is transmitted through structure. Then, in order to show the accuracy and the reliability of the present results, some comparisons are made between the achieved results and those of analytical as well as experimental results available in literature. Besides, the importance of using porous material as a core has been presented. Finally, some effective parameters have been studied in numerical results to inspect the insulation property of the current composite structure. [ABSTRACT FROM AUTHOR]

Published

2018

19. Reciprocal acoustic transmission experiment at Mihara-Seto in the Seto Inland Sea, Japan

Author

Yuji Sakuno, Takanori Sugano, Hidemi Mutsuda, Toshiyuki Takahashi, Naokazu Taniguchi, Kengo Yoshiki, and Hironori Yamamoto

Subjects

Oceanography, Acoustics and Ultrasonics, Environmental science, Acoustic transmission, Tidal current, Reciprocal

Published

2021

20. Simulations and Experimental Investigations on the Acoustic Characterization of Centrifugal Pumps of Different Specific Speed

Author

Christian Lehr, Andreas Linkamp, Daniel Aurich, and Andreas Brümmer

Subjects

centrifugal pump, pressure pulsation, acoustic transmission, scattering parameters, one-dimensional model, Mechanical engineering and machinery, TJ1-1570

Abstract

Subject of discussion are simulations and experimental investigations on the acoustic characterization of three single stage centrifugal pumps of different specific speed. In operation, these pump-types generate pressure pulsation at blade passing frequency, primarily due to rotor-volute-interaction. In order to determine the acoustic excitation it is necessary to know about the pumps’ acoustic transmission parameters. In this paper, a one-dimensional numerical model for transient time-domain simulation is presented, which takes into account the pump geometry as well as the volutes’ structural behaviour by means of the local effective speed of sound. Numerical results for the transmission characteristics of the three different pumps are shown in terms of scattering matrices and evaluated against parameters calculated from measurement results. The experimental analyses are carried out using dynamic pressure sensors in both the suction and the discharge pipe. Assuming solely plane wave propagation, the complex acoustic field on each side is evaluated independently. The so called “two source” method is then used to determine the transmission parameters of the pumps in standstill for a range of frequencies experimentally. Subsequently, the acoustic excitation at varying rotational speed is evaluated by means of measurements at the pumps in operation and presented as monopole and dipole source types for cavitation-free conditions.

Published

2019

21. Real-Time Communication Support for Underwater Acoustic Sensor Networks.

Author

Santos, Rodrigo, Orozco, Javier, Micheletto, Matias, Ochoa, Sergio F., Meseguer, Roc, Millan, Pere, and Molina, Carlos

Abstract

Underwater sensor networks represent an important and promising field of research due to the large diversity of underwater ubiquitous applications that can be supported by these networks, e.g., systems that deliver tsunami and oil spill warnings, or monitor submarine ecosystems. Most of these monitoring and warning systems require real-time communication in wide area networks that have a low density of nodes. The underwater communication medium involved in these networks is very harsh and imposes strong restrictions to the communication process. In this scenario, the real-time transmission of information is done mainly using acoustic signals, since the network nodes are not physically close. The features of the communication scenario and the requirements of the communication process represent major challenges for designers of both, communication protocols and monitoring and warning systems. The lack of models to represent these networks is the main stumbling block for the proliferation of underwater ubiquitous systems. This paper presents a real-time communication model for underwater acoustic sensor networks (UW-ASN) that are designed to cover wide areas with a low density of nodes, using any-to-any communication. This model is analytic, considers two solution approaches for scheduling the real-time messages, and provides a time-constraint analysis for the network performance. Using this model, the designers of protocols and underwater ubiquitous systems can quickly prototype and evaluate their solutions in an evolving way, in order to determine the best solution to the problem being addressed. The suitability of the proposal is illustrated with a case study that shows the performance of a UW-ASN under several initial conditions. This is the first analytic model for representing real-time communication in this type of network, and therefore, it opens the door for the development of underwater ubiquitous systems for several application scenarios. [ABSTRACT FROM AUTHOR]

Published

2017

22. Puhetta koneista

Author

Tiina Männistö-Funk

Subjects

Sociotechnical system, Late 19th century, Agency (philosophy), Comparative historical research, Speech synthesis, Sociology, Acoustic transmission, computer.software_genre, computer, Linguistics

Abstract

Koneellisesti tuotettu puhe on sekä teknisesti että sosiaalisesti erityinen teknologian ominaisuus. Tässä artikkelissa esitetään, että puhuvia koneita on syytä tarkastella omana sosioteknisenä kategorianaan, koska ihmismäiseen puheeseen liittyy koneen ja käyttäjän suhteen näkökulmasta monia erityisiä kysymyksiä. Elottomia esineitä on saatu puhumaan esihistoriallisista ajoista lähtien erilaisten äänensiirtotekniikoiden avulla, 1700-luvulta lähtien puhesynteesin avulla ja 1800-luvun lopulta lähtien myös äänitetyn puheen keinoin. 1900-luvun mittaan puhuvista koneista tuli osa modernia, teknistynyttä ääniympäristöä, ja erilaisia puhuvia robotteja esitellään yhä lupauksina tulevaisuuden älykkäistä koneista.Puhuvat koneet herättävät kuitenkin helposti ärsytyksen kaltaisia negatiivisia tunteita. Outoutta tai kauhua on pohdittu ongelmina robottien kohtaamisessa, mutta puheen rooli konekohtaamisissa on jäänyt vähälle huomiolle. Puhe toimijuuden muotona merkitsee ihmisen ja koneen suhteen asettumista neuvottelun alaiseksi erityisellä tavalla, jota kulttuurin- ja historiantutkimus voivat auttaa ymmärtämään.Talk of machines: Theoretical Perspectives to Speech TechnologiesMachinically produced speech is a special technological feature, both technically and socially. This article proposes treating talking machines as a sociotechnical category of their own, in order to pay due attention to the role of human-like speech in the relationship of machines and users. Inanimate objects have been given the power of speech from prehistoric times by diverse techniques of acoustic transmission. From the 18th century onwards they have been made to talk by means of mechanical speech synthesis and from the late 19th century on also by making use of voice recording technologies. During the 20th century, talking machines became a part of the modern, technological soundscape.Talking robots are still being showcased as promises of future machine intelligence. However, talking machines easily induce negative feelings, such as annoyance. The feelings of horror and uncanniness have often been brought up as problems in human-robot interaction, but the role of speech in these encounters has not attracted much attention. Speech as a form of agency negotiates the relationship of humans and machines in specific ways, which cultural studies and historical research can help to understand.

Published

2020

23. Two-scale numerical simulation of acoustic transmission in interaction with flow

Author

Lukeš, V., Rohan, E., Adámek, Vítězslav, Jonášová, Alena, Plánička, Stanislav, and Zajíček, Martin

Subjects

akustický přenos, numerical simulation, homogenization, dvoustupňové výpočty, homogenizace, acoustic transmission, numerická simulace, two-scale computations

Abstract

the grant project GA 2116406S of the Czech Science Foundation

Published

2022

24. Computational analysis of acoustic transmission through periodically perforated interfaces

Author

Rohan E. and Lukeš V.

Subjects

Acoustic transmission, Homogenization, Perforated layer, Numerical modelling, Mechanics of engineering. Applied mechanics, TA349-359

Abstract

The objective of the paper is to demonstrate the homogenization approach applied to modelling the acoustic transmission on perforated interfaces embedded in the acoustic fluid. We assume a layer, with periodically perforated obstacles, separating two half-spaces filled with the fluid. The homogenization method provides limit transmission conditions which can be prescribed at the homogenized surface representing the "limit" interface. The conditions describe relationship between jump of the acoustic pressures and the transversal acoustic velocity, on introducing the "in-layer pressure" which describes wave propagation in the tangent directions with respect to the interface.This approach may serve as a relevant tool for optimal design of devices aimed at attenuation of the acoustic waves, such as the engine exhaust mufflers or other structures fitted with sieves and grillages. We present numerical examples of wave propagation in a muffler-like structure illustrating viability of the approach when complex 3D geometries of the interface perforation are considered.

Published

2009

25. Modelling of acoustic transmission through perforated layer

Author

Lukeš V. and Rohan E.

Subjects

Acoustic transmission, Perforated layer, Homogenization technique, Mechanics of engineering. Applied mechanics, TA349-359

Abstract

The paper deals with modeling the acoustic transmission through a perforated interface plane separating two halfspaces occupied by the acoustic medium. We considered the two-scale homogenization limit of the standard acoustic problem imposed in the layer with the perforated periodic structure embedded inside. The homogenized transmission conditions govern the interface discontinuity of the acoustic pressure associated with the two halfspaces and the magnitude of the fictitious transversal acoustic velocity. By numerical examples we illustrate this novel approach of modeling the acoustic impedance of perforated interfaces.

Published

2007

26. A MAC Protocol to Support Monitoring of Underwater Spaces.

Author

Santos, Rodrigo, Orozco, Javier, Ochoa, Sergio F., Meseguer, Roc, Eggly, Gabriel, and Pistonesi, Marcelo F.

Abstract

Underwater sensor networks are becoming an important field of research, because of their everyday increasing application scope. Examples of their application areas are environmental and pollution monitoring (mainly oil spills), oceanographic data collection, support for submarine geolocalization, ocean sampling and early tsunamis alert. The challenge of performing underwater communications is well known, provided that radio signals are useless in this medium, and a wired solution is too expensive. Therefore, the sensors in these networks transmit their information using acoustic signals that propagate well under water. This data transmission type not only brings an opportunity, but also several challenges to the implementation of these networks, e.g., in terms of energy consumption, data transmission and signal interference. In order to help advance the knowledge in the design and implementation of these networks for monitoring underwater spaces, this paper proposes a MAC protocol for acoustic communications between the nodes, based on a self-organized time division multiple access mechanism. The proposal was evaluated using simulations of a real monitoring scenario, and the obtained results are highly encouraging. [ABSTRACT FROM AUTHOR]

Published

2016

27. INVESTIGATION OF ACOUSTIC CHARACTERISTICS AND DB REDUCTION OF MICROSPHERE-BASED PANELING ON DIVING WETSUITS

Author

Kartalov, Emil P., Denardo, Bruce C., Engineering Acoustics Academic Committee (EAAC), Young, Jared H., Kartalov, Emil P., Denardo, Bruce C., Engineering Acoustics Academic Committee (EAAC), and Young, Jared H.

Abstract

Scuba divers are exposed to potentially harmful temperatures and noise intensities while operating underwater. Standard neoprene wetsuits modified with glass-microsphere composite panels have been shown to improve the thermal capabilities of the suit and retain more of the diver’s body heat. While neoprene is an effective sound absorber itself, the acoustic properties and sound-proofing capabilities of the created composite panels were investigated. Several composite panels were used to shield a hydrophone receiver from a source signal over a range of frequencies from 10 Hz to 20 kHz and compared to a 7 mm neoprene sample. Results indicate a variable dB reduction in sound pressure over this range, with the measured intensity transmission coefficients of the composites being comparable to neoprene past a frequency of approximately 13 kHz. When used in tandem with neoprene, the material further reduces the measured pressure of the source signal. While not as effective as neoprene itself, the composite material shows potential for underwater soundproofing uses. Further experimentation with panel composition may yield a more effective sound absorbing material., Ensign, United States Navy, Approved for public release. Distribution is unlimited.

Published

2021

28. Zebra finch song and distance call amplitude measurements: A transmission experiment and observational transects in the natural environment

Author

Loning, Hugo, Griffith, Simon C., Naguib, Marc, Loning, Hugo, Griffith, Simon C., and Naguib, Marc

Abstract

Birdsong is typically seen as a long-range signal functioning in mate attraction and territory defense. Among birds, the zebra finch is the prime model organism in bioacoustics, yet almost exclusively studied in the lab. In the wild, however, zebra finch song differs strikingly from songbirds commonly studied in the wild as zebra finch males sing most after mating and in the absence of territoriality. Using data from the wild, we here provide an ecological context for a wealth of laboratory studies. By integrating calibrated sound recordings, sound transmission experiments and social ecology of zebra finches in the wild with insights from hearing physiology we show that wild zebra finch song is a very short-range signal with an audible range of about nine meters and that even the louder distance calls do not carry much farther (up to about fourteen meters). These integrated findings provide an ecological context for the interpretation of laboratory studies of this species and indicate that the vocal communication distance of the main laboratory species for avian acoustics contrasts strikingly with songbirds that use their song as a long-range advertisement signal.

Published

2021

29. A Novel Factor Graph and Cubature Kalman Filter Integrated Algorithm for Single-Transponder-Aided Cooperative Localization

Author

Wanlong Zhao, Lu Liu, Deyue Zou, and Huifeng Zhao

Subjects

Scheme (programming language), single transponder, Computer science, Cubature kalman filter, Science, Physics, QC1-999, cooperative localization, General Physics and Astronomy, factor graph, Acoustic transmission, Astrophysics, Article, QB460-466, CKF, Robustness (computer science), Outlier, Underwater, computer, Algorithm, Factor graph, computer.programming_language, Transponder

Abstract

Cooperative localization (CL) of underwater multi-AUVs is vital for numerous underwater operations. Single-transponder-aided cooperative localization (STCL) is regarded as a promising scheme for multi-AUVs CL, benefiting from the fact that an accurate reference is adopted. To improve the positioning accuracy and robustness of STCL, a novel Factor Graph and Cubature Kalman Filter (FGCKF)-integrated algorithm is proposed in this paper. In the proposed FGCKF, historical information can be efficiently used in measurement updating to overcome uncertain observation environments, which greatly helps to improve the performance of filtering progress. Furthermore, Adaptive CKF, sum product, and Maximum Correntropy Criterion (MCC) methods are designed to deal with outliers of acoustic transmission delay, sound velocity, and motion velocity, respectively. Simulations and experiments are conducted, and it is verified that the proposed FGCKF algorithm can improve positioning accuracy and robustness greatly than traditional filtering methods.

Published

2021

30. An Episode in the History of an Acoustic Mask

Author

Stephan Palmié

Subjects

History, media_common.quotation_subject, Repertoire, Religious studies, Art history, Ideology, Acoustic transmission, Social Sciences (miscellaneous), media_common

Abstract

In 1908, two black Cuban brothers, held a temple on Philadelphia’s North Fairmount Avenue, which appears to have combined Edinsonian sound technology with elements from the ritual repertoire of the Abakua male esoteric brotherhood. I suggest that the technologically enriched “echo” of the Leal brothers can be analysed heuristically as the locus of a remarkable convergence between phonic and auditory ideologies underlying the mediation of the divine in the Abakua, and acoustic transmission technologies through time and space – particularly telephony and phonography – that had begun to reconfigure the Western auditory worlds by the second half of the 19th century.

Published

2019

31. Passive acoustic damage detection of structural cavities using flow-induced acoustic excitations

Author

David J. Willis, Murat Inalpolat, Christopher Beale, and Christopher Niezrecki

Subjects

Damage detection, Materials science, Mechanical Engineering, Acoustics, Flow (psychology), Biophysics, 02 engineering and technology, 021001 nanoscience & nanotechnology, Acoustic transmission, 01 natural sciences, Fuselage, 0103 physical sciences, Passive detection, 0210 nano-technology, 010301 acoustics

Abstract

Cavities with different geometries represent the internal volumes of various engineering applications such as cabins of passenger cars, fuselages and wings of aircraft, and internal compartments of wind turbine blades. Transmissibility of acoustic excitation to and from these cavities is affected by material and cross-sectional properties of the structural cavity, as well as potential damage incurred. A new structural damage detection methodology that relies on the detectability of the changes in acoustic transmissibility across the boundaries of structural cavities is proposed. The methodology is described with a specific focus on the passive damage detection approach applied to cavity internal acoustic pressure responses under external flow-induced acoustic excitations. The approach is realized through a test plan that considers a wind turbine blade section subject to various damage types, severity levels, and locations, as well as wind speeds tested in a subsonic wind tunnel. A number of statistics-based metrics, including power spectral density estimates, band power differences from a known baseline, and the sum of absolute difference, were used to detect damage. The results obtained from the test campaign indicated that the passive acoustic damage detection approach was able to detect all considered hole-type damages as small as 0.32 cm in diameter and crack-type damages 1.27 cm in length. In general, the ability to distinguish damage from the baseline state improved as the damage increased in severity. Damage type, damage location, and flow speed influenced the ability to detect damage, but were not significant enough to prevent detection. This article serves as an overall proof of concept of the passive-based damage detection approach using flow-induced acoustic excitations on structural cavities of a wind turbine blade. The laboratory-scale results reveal that acoustic-based monitoring has great potential to be used as a new structural health monitoring technique for utility-scale wind turbine blades.

Published

2019

32. Design, characterization and evaluation of a laser-guided focused ultrasound system for preclinical investigations

Author

David S. Hersh, Meyer J. Fishman, Victor Frenkel, Ben A. Nguyen, Ali Mohammadabadi, Jesse A. Smith, and Pavlos Anastasiadis

Subjects

Simulations, Materials science, lcsh:Medical technology, Focused ultrasound, Ultrasonic Therapy, 0206 medical engineering, Transducers, Biomedical Engineering, 02 engineering and technology, Blood–brain barrier, law.invention, Biomaterials, Rats, Sprague-Dawley, Microhemorrhage, law, medicine, Pressure, Animals, Radiology, Nuclear Medicine and imaging, Sound pressure, Microbubbles, Radiological and Ultrasound Technology, Hydrophone, Research, Lasers, General Medicine, Equipment Design, Laser targeting, Laser, 020601 biomedical engineering, Characterization (materials science), Rats, medicine.anatomical_structure, Transducer, lcsh:R855-855.5, Blood-Brain Barrier, Hydrophone measurements, Direct coupling, Female, Acoustic transmission, Hydrogel phantoms, Biomedical engineering

Abstract

Background The clinical applications of transcranial focused ultrasound continue to expand and include ablation as well as drug delivery applications in the brain, where treatments are typically guided by MRI. Although MRI-guided focused ultrasound systems are also preferred for many preclinical investigations, they are expensive to purchase and operate, and require the presence of a nearby imaging center. For many basic mechanistic studies, however, MRI is not required. The purpose of this study was to design, construct, characterize and evaluate a portable, custom, laser-guided focused ultrasound system for noninvasive, transcranial treatments in small rodents. Methods The system comprised an off-the-shelf focused ultrasound transducer and amplifier, with a custom cone fabricated for direct coupling of the transducer to the head region. A laser-guidance apparatus was constructed with a 3D stage for accurate positioning to 1 mm. Pressure field simulations were performed to demonstrate the effects of the coupling cone and the sealing membrane, as well as for determining the location of the focus and acoustic transmission across rat skulls over a range of sizes. Hydrophone measurements and exposures in hydrogels were used to assess the accuracy of the simulations. In vivo treatments were performed in rodents for opening the blood–brain barrier and to assess the performance and accuracy of the system. The effects of varying the acoustic pressure, microbubble dose and animal size were evaluated in terms of efficacy and safety of the treatments. Results The simulation results were validated by the hydrophone measurements and exposures in the hydrogels. The in vivo treatments demonstrated the ability of the system to open the blood–brain barrier. A higher acoustic pressure was required in larger-sized animals, as predicted by the simulations and transmission measurements. In a particular sized animal, the degree of blood–brain barrier opening, and the safety of the treatments were directly associated with the microbubble dose. Conclusion The focused ultrasound system that was developed was found to be a cost-effective alternative to MRI-guided systems as an investigational device that is capable of accurately providing noninvasive, transcranial treatments in rodents.

Published

2019

33. Cortical bone properties in the Brtl/+ mouse model of Osteogenesis imperfecta as evidenced by acoustic transmission microscopy

Author

Peter Fratzl, Wayne A. Cabral, Joan C. Marini, Andreas Roschger, Nadja Fratzl-Zelman, Stéphane Blouin, Paul Roschger, and Klaus Klaushofer

Subjects

Materials science, Microscopy, Acoustic, Biomedical Engineering, 02 engineering and technology, Acoustic transmission, Article, Biomaterials, Mice, 03 medical and health sciences, 0302 clinical medicine, Nuclear magnetic resonance, Microscopy, Bone material, Cortical Bone, medicine, Animals, Femur, Bone level, Mechanical Phenomena, 030206 dentistry, Osteogenesis Imperfecta, Backscattered electron, 021001 nanoscience & nanotechnology, medicine.disease, Biomechanical Phenomena, Disease Models, Animal, Mineral density, medicine.anatomical_structure, Mechanics of Materials, Osteogenesis imperfecta, Cortical bone, 0210 nano-technology

Abstract

Higher skeletal fragility has been established for the Brtl/+ mouse model of osteogenesis imperfecta at the whole bone level, but previous investigations of mechanical properties at the bone material level were inconclusive. Bone material was analyzed separately at endosteal (ER) and periosteal regions (PR) on transverse femoral midshaft sections for 2-month old mice (wild-type n = 6; Brtl/+ n = 6). Quantitative backscattered electron imaging revealed that the mass density computed from mineral density maps was higher in PR than in ER for both wild-type (+2.1%, p < 0.05) and Brtl/+ mice (+1.8%, p < 0.05). Electron induced X-ray fluorescence analysis indicated significantly lower atomic Ca/P ratios and higher Na/Ca, Mg/Ca and K/Ca ratios in PR bone compared to ER independently of genotype. Second harmonic generation microscopy indicated that the occurrence of periodically alternating collagen orientation in ER of Brtl/+ mice was strongly reduced compared to wild-type mice. Scanning acoustic microscopy in time of flight mode revealed that the sound velocity and Young's modulus (estimated based on sound velocity and mass density maps) were significantly greater in PR (respectively + 6% and +15%) compared to ER in wild-type mice but not in Brtl/+ mice. ER sound velocity and Young's modulus were significantly increased in Brtl/+ mice (+9.4% and +22%, respectively) compared to wild-type mice. These data demonstrate that the Col1a1 G349C mutation in Brtl/+ mice affects the mechanical behavior of bone material predominantly in the endosteal region by altering the collagen orientation.

Published

2019

34. Real-Time Communication Support for Underwater Acoustic Sensor Networks

Author

Rodrigo Santos, Javier Orozco, Matias Micheletto, Sergio F. Ochoa, Roc Meseguer, Pere Millan, and Carlos Molina

Subjects

underwater sensor networks, underwater monitoring, MAC protocol, acoustic transmission, submarine ubiquitous applications, Chemical technology, TP1-1185

Abstract

Underwater sensor networks represent an important and promising field of research due to the large diversity of underwater ubiquitous applications that can be supported by these networks, e.g., systems that deliver tsunami and oil spill warnings, or monitor submarine ecosystems. Most of these monitoring and warning systems require real-time communication in wide area networks that have a low density of nodes. The underwater communication medium involved in these networks is very harsh and imposes strong restrictions to the communication process. In this scenario, the real-time transmission of information is done mainly using acoustic signals, since the network nodes are not physically close. The features of the communication scenario and the requirements of the communication process represent major challenges for designers of both, communication protocols and monitoring and warning systems. The lack of models to represent these networks is the main stumbling block for the proliferation of underwater ubiquitous systems. This paper presents a real-time communication model for underwater acoustic sensor networks (UW-ASN) that are designed to cover wide areas with a low density of nodes, using any-to-any communication. This model is analytic, considers two solution approaches for scheduling the real-time messages, and provides a time-constraint analysis for the network performance. Using this model, the designers of protocols and underwater ubiquitous systems can quickly prototype and evaluate their solutions in an evolving way, in order to determine the best solution to the problem being addressed. The suitability of the proposal is illustrated with a case study that shows the performance of a UW-ASN under several initial conditions. This is the first analytic model for representing real-time communication in this type of network, and therefore, it opens the door for the development of underwater ubiquitous systems for several application scenarios.

Published

2017

35. Experimental investigation of mechanical, acoustic and hybrid metamaterial designs for enhanced and multi-band electric motor noise dissipation.

Author

Tian, Zhenhuan, Bennett, J., Yang, J., Lawrie, T., Elmadih, W., Bardalai, A., Gerada, C., Zhu, Jian, and Chronopoulos, D.

Subjects

*ELECTRIC noise, *ELECTRIC motors, *NOISE control, *ACOUSTIC emission, *METAMATERIALS, *SOUND waves, *ELASTIC waves

Abstract

Acoustic metastructures exhibit an unprecedented ability to arbitrarily manipulate the properties of sound waves, including amplitude and phase modulation which has attracted much attention in both the academic and industrial communities. Design of metastructures has been extensively investigated for the purpose of the independent manipulation of acoustic and elastic waves. It is up to now unclear however if the optimal dissipation approach involves locally resonant structural elements, or locally resonant acoustic cavities or a hybrid mix of both noise abatement mechanisms. To study this problem, we investigate numerically and experimentally the noise reduction performance of acoustic and mechanically locally resonant structures and how they perform when integrated into the same application scenario. Taking the noise emission of an electric motor as the excitation regime for our study, the acoustic and mechanical metamaterial structures with respective C-shape and T-shaped resonators are judiciously designed to maximize noise dissipation within two targeted frequency bands where the motor noise peaks. A hybrid structure with a mix of both resonators is also designed. The results demonstrate that all three metastructure designs improved the noise attenuation performance with an additional sound insertion loss of up to 16 dB when compared to a flat wall structure of equivalent mass. The findings in this work demonstrate that significant noise attenuation can be obtained by incorporating these acoustic and mechanical meta-atoms into a wall architecture which may have great potential for real world applications such as surrounding electric motors which tend to emit monotonic and irritating noise. • We identify pronounced noise signatures for a typical electric motor. • Metastructures are designed for damping noise within two targeted frequency bands. • The mechanical resonance, acoustic resonance and a hybrid design for noise damping. • Large-scalemetastructures are experimentally tested within an anechoic chamber. [ABSTRACT FROM AUTHOR]

Published

2022

36. INVESTIGATION OF ACOUSTIC CHARACTERISTICS AND DB REDUCTION OF MICROSPHERE-BASED PANELING ON DIVING WETSUITS

Author

Young, Jared H., Kartalov, Emil P., Denardo, Bruce C., and Engineering Acoustics Academic Committee (EAAC)

Subjects

wetsuit, diver, frequency response, acoustic transmission

Abstract

Scuba divers are exposed to potentially harmful temperatures and noise intensities while operating underwater. Standard neoprene wetsuits modified with glass-microsphere composite panels have been shown to improve the thermal capabilities of the suit and retain more of the diver’s body heat. While neoprene is an effective sound absorber itself, the acoustic properties and sound-proofing capabilities of the created composite panels were investigated. Several composite panels were used to shield a hydrophone receiver from a source signal over a range of frequencies from 10 Hz to 20 kHz and compared to a 7 mm neoprene sample. Results indicate a variable dB reduction in sound pressure over this range, with the measured intensity transmission coefficients of the composites being comparable to neoprene past a frequency of approximately 13 kHz. When used in tandem with neoprene, the material further reduces the measured pressure of the source signal. While not as effective as neoprene itself, the composite material shows potential for underwater soundproofing uses. Further experimentation with panel composition may yield a more effective sound absorbing material. Ensign, United States Navy Approved for public release. Distribution is unlimited.

Published

2021

37. Design approach of perforated labyrinth-based acoustic metasurface for selective acoustic levitation manipulation

Author

Wei Xu, Shuhua Fang, Ling Qin, Jiyao Wang, and Zhike Xu

Subjects

Physics, Multidisciplinary, Science, Acoustics, Low-pass filter, Physics::Optics, 02 engineering and technology, 021001 nanoscience & nanotechnology, Acoustic transmission, Acoustic levitation, 01 natural sciences, Resonance (particle physics), Article, Mechanical engineering, High transmission, 0103 physical sciences, Path (graph theory), Reflection (physics), Medicine, 010306 general physics, 0210 nano-technology, High-pass filter

Abstract

This paper proposes a metasurface design approach with perforated labyrinthine path coil structure to manipulate the acoustic transmission with inexpensive materials. The medium in the labyrinthine path coils in this design is air, but not limited to air. A systematic approach has been proposed for the unit cell design of acoustic metamaterials with adjustable resonance peak frequencies and bandgap width. The theory demonstrates that the length of pipe segments determines resonance peak frequencies and the cross-sectional area ratio adjusts the bandgap width. The proposed design approach uses an equivalent pipe circuit based analytical model to design the high transmission (high pass) and high reflection (low pass) unit cell. The simulation and experiment has been performed to evaluate the validity of the theory. Although there exists some assumptions in the theory, the theory still has enough accuracy to guide the metasurface design illustrated by the simulation and experiment results.

Published

2021

38. Investigation on the influence coupling drilling fluid and formation boundary on acoustic wave propagation in drill string

Author

Ma, Tianshou, Zou, Jiayan, Chen, Ping, and Liu, Haosheng

Published

2020

39. Abnormal acoustic transmission in a waveguide with perforated screens

Author

Lucas Chesnel, Sergei A. Nazarov, Inversion of Differential Equations For Imaging and physiX (IDEFIX), Inria Saclay - Ile de France, Institut National de Recherche en Informatique et en Automatique (Inria)-Institut National de Recherche en Informatique et en Automatique (Inria)-École polytechnique (X)-EDF (EDF), Centre de Mathématiques Appliquées - Ecole Polytechnique (CMAP), École polytechnique (X)-Centre National de la Recherche Scientifique (CNRS), and St Petersburg State University (SPbU)

Subjects

Physics, abnormal transmission, Asymptotic analysis, Acoustics, Mode (statistics), 02 engineering and technology, waveguides, Acoustic transmission, law.invention, Piston, Resonator, asymptotic analysis, Mathematics - Analysis of PDEs, 020303 mechanical engineering & transports, 0203 mechanical engineering, Transmission (telecommunications), Mechanics of Materials, law, FOS: Mathematics, Waveguide (acoustics), [MATH.MATH-AP]Mathematics [math]/Analysis of PDEs [math.AP], General Materials Science, perforated screens, Energy (signal processing), Analysis of PDEs (math.AP)

Abstract

International audience; We consider the propagation of the piston mode in an acoustic waveguide obstructed by two screens with small holes. In general, due to the features of the geometry, almost no energy of the incident wave is transmitted through the structure. The goal of this article is to show that tuning carefully the distance between the two screens, which form a resonator, one can get almost complete transmission. We obtain an explicit criterion, not so obvious to intuit, for this phenomenon to happen. Numerical experiments illustrate the analysis.

Published

2021

40. Sounding and modeling of the indoor aerial acoustic transmission channel

Author

Guido H. Bruck and Peter Jung

Subjects

Computer Science::Robotics, Kommunikationswissenschaft, Depth sounding, Computer science, Acoustics, Channel (broadcasting), Data_CODINGANDINFORMATIONTHEORY, Electrical and Electronic Engineering, Acoustic transmission, Computer Science::Information Theory

Abstract

The authors verify that the indoor aerial acoustic transmission channel regarding small-scale application environments, for example, a car cabin, is a quasi-wide sense stationary uncorrelated scattering (QWSSUS) channel like radio channels. To the best knowledge of the authors, the QWSSUS feature of the indoor aerial acoustic transmission channel has never been evaluated before. Setting out from the QWSSUS concept, the channel modeling by means of correlation functions is proposed. Also, parameter sets that can be used in channel simulations are suggested.

Published

2021

41. Zebra finch song and distance call amplitude measurements: A transmission experiment and observational transects in the natural environment

Subjects

wild population, Behavioral Ecology, Gedragsecologie, Taeniopygia gutatta, biological sciences, zebra finch, WIAS, transect counts, acoustic transmission, calibration, acoustic recordings

Abstract

Birdsong is typically seen as a long-range signal functioning in mate attraction and territory defense. Among birds, the zebra finch is the prime model organism in bioacoustics, yet almost exclusively studied in the lab. In the wild, however, zebra finch song differs strikingly from songbirds commonly studied in the wild as zebra finch males sing most after mating and in the absence of territoriality. Using data from the wild, we here provide an ecological context for a wealth of laboratory studies. By integrating calibrated sound recordings, sound transmission experiments and social ecology of zebra finches in the wild with insights from hearing physiology we show that wild zebra finch song is a very short-range signal with an audible range of about nine meters and that even the louder distance calls do not carry much farther (up to about fourteen meters). These integrated findings provide an ecological context for the interpretation of laboratory studies of this species and indicate that the vocal communication distance of the main laboratory species for avian acoustics contrasts strikingly with songbirds that use their song as a long-range advertisement signal.

Published

2021

42. A MAC Protocol to Support Monitoring of Underwater Spaces

Author

Rodrigo Santos, Javier Orozco, Sergio F. Ochoa, Roc Meseguer, Gabriel Eggly, and Marcelo F. Pistonesi

Subjects

underwater sensor networks, underwater monitoring, MAC protocol, acoustic transmission, Chemical technology, TP1-1185

Abstract

Underwater sensor networks are becoming an important field of research, because of their everyday increasing application scope. Examples of their application areas are environmental and pollution monitoring (mainly oil spills), oceanographic data collection, support for submarine geolocalization, ocean sampling and early tsunamis alert. The challenge of performing underwater communications is well known, provided that radio signals are useless in this medium, and a wired solution is too expensive. Therefore, the sensors in these networks transmit their information using acoustic signals that propagate well under water. This data transmission type not only brings an opportunity, but also several challenges to the implementation of these networks, e.g., in terms of energy consumption, data transmission and signal interference. In order to help advance the knowledge in the design and implementation of these networks for monitoring underwater spaces, this paper proposes a MAC protocol for acoustic communications between the nodes, based on a self-organized time division multiple access mechanism. The proposal was evaluated using simulations of a real monitoring scenario, and the obtained results are highly encouraging.

Published

2016

43. Localization of acoustic modes in periodic porous silicon structures.

Author

Lazcano, Zorayda, Meza, Octavio, and Arriaga, Jesús

Subjects

POROUS silicon, SOUND waves, MULTILAYERS, BAND gaps, THICKNESS measurement, PHONONIC crystals, CRYSTAL structure

Abstract

The propagation of longitudinal acoustic waves in multilayer structures based on porous silicon and the experimental measurement of acoustic transmission for the structures in the gigahertz range are reported and studied theoretically. The considered structures exhibit band gaps in the transmission spectrum and these are localized modes inside the band gap, coming from defect layers introduced in periodic systems. The frequency at which the acoustic resonances appear can be tuned by changing the porosity and/or thickness of the defect layer. [ABSTRACT FROM AUTHOR]

Published

2014

44. High frequency thermomechanical study of heterogeneous materials with interfaces

Author

Luo, Haoming, Laboratoire de Mécanique des Contacts et des Structures [Villeurbanne] (LaMCoS), Institut National des Sciences Appliquées de Lyon (INSA Lyon), Institut National des Sciences Appliquées (INSA)-Université de Lyon-Institut National des Sciences Appliquées (INSA)-Université de Lyon-Centre National de la Recherche Scientifique (CNRS), Mécanique Multiéchelle pour les solides (MIMESIS), Institut National des Sciences Appliquées (INSA)-Université de Lyon-Institut National des Sciences Appliquées (INSA)-Université de Lyon-Centre National de la Recherche Scientifique (CNRS)-Institut National des Sciences Appliquées de Lyon (INSA Lyon), Université de Lyon, Anne Tanguy, STAR, ABES, Université de Lyon-Institut National des Sciences Appliquées (INSA)-Université de Lyon-Institut National des Sciences Appliquées (INSA)-Centre National de la Recherche Scientifique (CNRS), and Université de Lyon-Institut National des Sciences Appliquées (INSA)-Université de Lyon-Institut National des Sciences Appliquées (INSA)-Centre National de la Recherche Scientifique (CNRS)-Institut National des Sciences Appliquées de Lyon (INSA Lyon)

Subjects

Inclusion, Finite element method, Nanocomposite, Heterogeneous material, Applied Mechanics, Transfert thermique, Nanophotonique, Attenuation, Mécanique analytique, Numerical simulation, Matériau amorphe, Matériau hétérogène, [SPI.MECA]Engineering Sciences [physics]/Mechanics [physics.med-ph], [SPI.MECA] Engineering Sciences [physics]/Mechanics [physics.med-ph], Acoustic emission, Amorphous material, Transfert acoustique, Simulation numérique, Méthode par éléments finis, Nanophotonics, Atténuation, Acoustic transmission

Abstract

Heat transfer is actually intimately related to the sound propagation (acoustic transfer) in materials, as in insulators and semi-conductors the main heat carriers are acoustic phonons. The concept of the presence of interfaces has been largely exploited for efficiently manipulating phonons from long-wavelength to nanometric wavelengths, i.e., frequencies in THz regime, responsible for thermal transport at room temperature. In this thesis, the finite element method is used to perform transient analysis of wavepacket propagation in different mediums. I started with a parametric study of attenuation of acoustic wave-packets in a 2D semi-infinite elastic system with periodic circular interfaces. Three key parameters are investigated, including rigidity contrast, interface density and phonon wavelength. Different energy transfer regimes (propagative, diffusive, and localized) are identified allowing to understand the phonon contribution to thermal transport. Besides the circular interfaces, mechanical response and acoustic attenuation for different types of interfaces are also investigated, such as Eshelby’s inclusion, dendritic shape inclusion and porous materials with ordered/disordered holes. In order to extend the study to amorphous materials, I also considered a heterogeneous medium with random rigidities distributed in space according to a Gaussian distribution based on the theory of heterogeneous shear elasticity of glasses. Finally yet importantly, viscoelastic constitutive laws are proposed to take into account the frequency-dependent intrinsic phonon attenuation in glasses, with the aim of reproducing such intrinsic attenuation using a homogeneous viscous medium. Finite element simulation confirms that a continuum model may strictly follow the atomistic attenuation (G) for a well-calibrated macroscopic linear viscoelastic constitutive law. Compared with the experimental data in a-SiO2, our second constitutive law reproduces qualitatively and quantitatively the three regimes of acoustic attenuation versus frequency : successively Γ∝ω^2,ω^4,ω^2., Le transfert de chaleur est intimement lié à la propagation du son (transfert acoustique) dans les matériaux, par exemple dans les isolants et les semi-conducteurs, les principaux vecteurs d’énergie sont des phonons acoustiques. Le concept de présence d’interfaces a été largement exploité pour manipuler efficacement les phonons des longueurs d’onde macroscopiques aux longueurs d’onde nanométriques. Les derniers correspondent aux fréquences en régime THz, qui sont responsables du transport thermique à température ambiante. Dans cette thèse, la méthode des éléments finis est utilisée pour effectuer des analyses transitoires de la propagation des paquets d’ondes dans différents milieux à 2D. Elle est commencée par une étude paramétrique de l’atténuation des paquets d’ondes dans un système élastique semi-infini avec des interfaces circulaires périodiques. Trois paramètres clés sont étudiés, notamment le contraste de rigidité, la densité d’interface et la longueur d’onde des phonons. Différents régimes de transfert (propagatif, diffusif et localisé) sont identifiés, qui permettent d’identifier la contribution des phonons à la conductivité thermique. Outre les interfaces circulaires, la réponse mécanique et l’atténuation acoustique pour différents types d’interfaces sont également étudiées, telles que l’inclusion de forme dendritique, l’inclusion d’Eshelby, et les matériaux poreux avec des pores ordonnés / désordonnés. Afin d’étendre l’étude aux matériaux amorphes, j’ai également considéré un milieu hétérogène avec des rigidités aléatoires réparties dans l’espace selon une distribution gaussienne basée sur la théorie de l’élasticité de cisaillement hétérogène des verres. Enfin et surtout, deux versions de lois de comportement viscoélastiques sont proposées pour prendre en compte l’atténuation intrinsèque des phonons dépendant de la fréquence dans les verres, dans le but qu’un milieu visqueux homogène puisse reproduire cette atténuation intrinsèque. La simulation par éléments finis confirme qu’un modèle continu peut suivre strictement l’atténuation atomistique (G) avec une loi de comportement viscoélastique linéaire macroscopique bien calibrée. Par rapport aux données expérimentales de a-SiO2, notre deuxième loi de comportement reproduit qualitativement et quantitativement les trois régimes d’atténuation acoustique en fonction de la fréquence : successivement Γ ∝ ω^2,ω^4,ω^2.

Published

2020

45. Non-reciprocal acoustics in a viscous environment

Author

Arup Neogi, Arkadii Krokhin, Hyeonu Heo, Dylan Wages, Tae-Youl Choi, Dmitrii Shymkiv, Yurii Zubov, and Ezekiel Walker

Subjects

Physics, Ideal (set theory), Computer Science::Information Retrieval, General Mathematics, General Engineering, Anisotropic crystal, General Physics and Astronomy, Mechanics, Acoustic transmission, 01 natural sciences, Crystal, Physics::Fluid Dynamics, Inviscid flow, 0103 physical sciences, 010306 general physics, 010301 acoustics, Reciprocal, Research Article

Abstract

It is demonstrated that acoustic transmission through a phononic crystal with anisotropic solid scatterers becomes non-reciprocal if the background fluid is viscous. In an ideal (inviscid) fluid, the transmission along the direction of broken P symmetry is asymmetric. This asymmetry is compatible with reciprocity since time-reversal symmetry ( T symmetry) holds. Viscous losses break T symmetry, adding a non-reciprocal contribution to the transmission coefficient. The non-reciprocal transmission spectra for a phononic crystal of metallic circular cylinders in water are experimentally obtained and analysed. The surfaces of the cylinders were specially processed in order to weakly break P symmetry and increase viscous losses through manipulation of surface features. Subsequently, the non-reciprocal part of transmission is separated from its asymmetric reciprocal part in numerically simulated transmission spectra. The level of non-reciprocity is in agreement with the measure of broken P symmetry. The reported study contradicts commonly accepted opinion that linear dissipation cannot be a reason leading to non-reciprocity. It also opens a way for engineering passive acoustic diodes exploring the natural viscosity of any fluid as a factor leading to non-reciprocity.

Published

2020

46. WaveQ3D: Fast and Accurate Acoustic Transmission Loss (TL) Eigenrays, in Littoral Environments

Author

Sean M. Reilly

Subjects

Engineering, business.industry, Acoustics, Littoral zone, business, Acoustic transmission

Published

2020

47. Thermally Tunable Surface Acoustic Wave Cavities

Author

Mauricio M. de Lima, Andre Luiz Oliveira Bilobran, Alberto García-Cristóbal, Andrés Cantarero, and Paulo V. Santos

Subjects

Frequency response, Acoustic field, Condensed Matter - Materials Science, Materials science, Acoustics and Ultrasonics, business.industry, Surface acoustic wave, Materials Science (cond-mat.mtrl-sci), FOS: Physical sciences, Substrate (electronics), Physics - Applied Physics, Applied Physics (physics.app-ph), Acoustic transmission, 01 natural sciences, Dc voltage, Transmission (telecommunications), 0103 physical sciences, Optoelectronics, Electrical and Electronic Engineering, business, Joule heating, 010301 acoustics, Instrumentation

Abstract

We experimentally demonstrate the dynamical tuning of the acoustic field in a surface acoustic wave (SAW) cavity defined by a periodic arrangement of metal stripes on LiNbO3 substrate. Applying a dc voltage to the ends of the metal grid results in a temperature rise due to resistive heating that changes the frequency response of the device up to 0.3%, which can be used to control the acoustic transmission through the structure. The timescale of the switching is demonstrated to be of about 200 ms. In addition, we have also performed finite-element simulations of the transmission spectrum of a model system, which exhibits a temperature dependence consistent with the experimental data. The advances shown here enable easy, continuous, dynamical control and could be applied for a variety of substrates.

Published

2020

48. Nonreciprocal Acoustic Transmission using Lithium Niobate Parity-Time-Symmetric Resonators

Author

Yaowen Hu, Wenbo Mao, Linbo Shao, Lan Yang, Marko Loncar, Neil Sinclair, and Smarak Maity

Subjects

Physics, Phonon, Acoustics, Surface acoustic wave, Lithium niobate, Physics::Optics, Parity (physics), 02 engineering and technology, Acoustic wave, 021001 nanoscience & nanotechnology, Acoustic transmission, 01 natural sciences, Piezoelectricity, 010309 optics, Resonator, chemistry.chemical_compound, chemistry, Computer Science::Sound, 0103 physical sciences, 0210 nano-technology

Abstract

Taking advantage of the piezoelectricity of lithium niobate, we achieve nonreciprocal transmission of 10 decibels for a 200-MHz surface acoustic wave using parity-time- symmetric resonators and demonstrate one-way circulation of acoustic waves.

Published

2020

49. Acoustic Transmission Factor through the Rat Skull as a Function of Body Mass, Frequency and Position

Author

Benoit Larrat, Erwan Selingue, Matthieu Gerstenmayer, Benjamin Fellah, Rémi Magnin, Service NEUROSPIN (NEUROSPIN), Université Paris-Saclay-Direction de Recherche Fondamentale (CEA) (DRF (CEA)), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA), The authors thank the CEA 'Technologies for Health' transverse program, which funded this work, and ANR-17-CE19-0025,3BOPUS,Développement et validation d'un dispositif clinique d'ouverture de la barrière hémato-encéphalique par ultrasons focalisés transcraniens(2017)

Subjects

Male, 0301 basic medicine, Materials science, Acoustics and Ultrasonics, Focused ultrasound, Biophysics, Rats, Sprague-Dawley, [SPI]Engineering Sciences [physics], 03 medical and health sciences, Beam (nautical), otorhinolaryngologic diseases, medicine, Animals, Insertion loss, Radiology, Nuclear Medicine and imaging, Sound pressure, Ultrasonography, [SPI.ACOU]Engineering Sciences [physics]/Acoustics [physics.class-ph], Radiological and Ultrasound Technology, Attenuation, Body Weight, Skull, Acoustics, Rats, Transcranial Doppler, 030104 developmental biology, medicine.anatomical_structure, Transmission (telecommunications), Reflection (physics), [SDV.IB]Life Sciences [q-bio]/Bioengineering, Acoustic transmission, Rat skull, Biomedical engineering

Abstract

International audience; In many transcranial ultrasound studies on rats, the transmission factor is assumed to be independent of animal weight and losses resulting from non-normal incidence angles of the beam are not accounted for. In this study, we measured acoustic transmission factors through 13 excised skulls of male Sprague-Dawley rats weighing between 90 and 520g, at different positions on each skull and at 1, 1.25, 1.5, 1.75 and 2MHz. Our results revealed that insertion loss through rat skull increases linearly with both body mass and frequency and strongly depends on the position, decreasing from the front to the back and from the midline to the lateral sides. Skull thickness also scales linearly with body mass. Reflection explains the main part of the insertion loss compared with attenuation and aberration. These data are helpful in predicting the acoustic pressure at the focus in the brain

Published

2018

50. Analysis of Sound Absorption Characteristics of Acoustic Ducts with Periodic Additional Multi-Local Resonant Cavities

Author

Ting Wang, Meixia Chen, and Junyi Liu

Subjects

periodic structure, Physics, Range (particle radiation), local resonance, genetic structures, Physics and Astronomy (miscellaneous), General Mathematics, Transmission loss, Acoustics, Resonance, Resonant cavity, sound absorption characteristics, Acoustic transmission, acoustic pipe, Radio spectrum, symbols.namesake, Chemistry (miscellaneous), Helmholtz free energy, Broadband, QA1-939, Computer Science (miscellaneous), symbols, Mathematics

Abstract

With the aim of applying various Helmholtz resonant cavities to achieve low-frequency sound absorption structures, a pipe structure with periodic, additional, symmetrical, multi-local resonant cavities is proposed. A thin plate with additional mass is placed in the cylindrical Helmholtz resonant cavity structure to form a symmetric resonant cavity structure and achieve multi-local resonance. The simulation results show that the periodic structure proposed in this paper can produce multiple, high acoustic transmission loss peaks and multiple lower broadband sound absorption frequency bands in the low-frequency range. In this paper, this idea is also extended to the Helmholtz resonant cavity embedded with multiple additional mass plates. The results show that the periodic arrangement of the multi-local resonant symmetric cavity inserted into multiple plates with mass can significantly increase its transmission loss and show a better performance on low-frequency sound absorption characteristics.

Published

2021