Your search keyword '"Acoustic Streaming"' showing total 4,623 results

1. Acoustic rotation of multiple subwavelength cylinders for three-dimensional topography reconstruction.

Author

Huang, Laixin, Bao, Shi-Chun, Cai, Feiyan, Meng, Long, Zhou, Wei, Zhou, Juan, Kong, Deqing, Li, Fei, and Zheng, Hairong

Subjects

*ROTATIONAL motion, *PHONONIC crystals, *ACOUSTIC streaming, *MICROFLUIDIC devices, *TOPOGRAPHY, *SOUND design

Abstract

Accurate rotation of microparticles is of great significance in micro-rotors, multi-angle microscopic observation, microbial three-dimensional phenotyping, and microsystem assembly. However, most methods can only rotate a single object, thus limiting the throughput. In this study, we realized the simultaneous rotation of many trapped and aligned subwavelength glass cylinders inside an evanescent wave field excited by a resonant phononic crystal plate. The unique feature of the rotation lies in its periodic distribution as well as the rotation axis being perpendicular to the acoustic axis. The rotary power originates from viscous torque generated by the evanescent wave-induced near-boundary acoustic streaming's asymmetry distribution on the trapped cylinder. Furthermore, the three-dimensional topographies of rotated cylinders can be reconstructed from the microscopic images under different rotating angles. Our findings can pave the way toward developing simple, disposable, and scalable microfluidic devices for massive subwavelength acoustic rotation by carefully designing acoustic metamaterials. [ABSTRACT FROM AUTHOR]

Published

2023

2. Acoustic radiation forces on spherical objects in a viscous fluid by Bessel beams.

Author

Fan, Xudong

Subjects

*ACOUSTIC radiation force, *BESSEL beams, *ACOUSTIC streaming, *DRAG force, *ELASTIC plates & shells, *FINITE element method

Abstract

This study investigates acoustic radiation forces on spherical objects generated by Bessel beams in a viscous fluid. Radiation forces on elastic spheres and shells of different materials are examined using viscid expression with the thermoviscous correction included, and the results are then compared with numerical simulations based on the finite element method. The Stokes drag force for zero-order Bessel waves was theoretically derived, and in turn, a practical example of negative radiation forces is proposed and investigated together with the gravity, the buoyancy, and the drag force from acoustic streaming. It is found that the negative pulling force exists even including the positive forces from the other sources; however, the parameter regions for pulling forces are reduced especially for small objects. This work helps the further study of particle manipulations by acoustic Bessel beams in viscous fluids and also guides the experimental realization of acoustic tractor beams. [ABSTRACT FROM AUTHOR]

Published

2023

3. Characterization of the acoustic cavitation in ionic liquids in a horn-type ultrasound reactor.

Author

Schieppati, Dalma, Mohan, Mood, Blais, Bruno, Fattahi, Kobra, Patience, Gregory, Simmons, Blake, Singh, Seema, and Boffito, Daria

Subjects

Acoustic pressure, Acoustic streaming, Active region, Cavitation, Ionic liquid, Ultrasound

Abstract

Most ultrasound-based processes root in empirical approaches. Because nearly all advances have been conducted in aqueous systems, there exists a paucity of information on sonoprocessing in other solvents, particularly ionic liquids (ILs). In this work, we modelled an ultrasonic horn-type sonoreactor and investigated the effects of ultrasound power, sonotrode immersion depth, and solvents thermodynamic properties on acoustic cavitation in nine imidazolium-based and three pyrrolidinium-based ILs. The model accounts for bubbles, acoustic impedance mismatch at interfaces, and treats the ILs as incompressible, Newtonian, and saturated with argon. Following a statistical analysis of the simulation results, we determined that viscosity and ultrasound input power are the most significant variables affecting the intensity of the acoustic pressure field (P), the volume of cavitation zones (V), and the magnitude of the maximum acoustic streaming surface velocity (u). V and u increase with the increase of ultrasound input power and the decrease in viscosity, whereas the magnitude of negative P decreases as ultrasound power and viscosity increase. Probe immersion depth positively correlates with V, but its impact on P and u is insignificant. 1-alkyl-3-methylimidazolium-based ILs yielded the largest V and the fastest acoustic jets - 0.77 cm3 and 24.4 m s-1 for 1-ethyl-3-methylimidazolium chloride at 60 W. 1-methyl-3-(3-sulfopropyl)-imidazolium-based ILs generated the smallest V and lowest u - 0.17 cm3 and 1.7 m s-1 for 1-methyl-3-(3-sulfopropyl)-imidazolium p-toluene sulfonate at 20 W. Sonochemiluminescence experiments validated the model.

Published

2024

4. Acoustic enrichment of sperm for in vitro fertilization.

Author

Chunqiu Zhang, Ning Rong, Ziyi Lin, Peng-Qi Li, Jingyao Shi, Wei Zhou, Lili Niu, Fei Li, Rongxin Tang, Lei Li, and Long Meng

Subjects

*ACOUSTIC streaming, *INTERDIGITAL transducers, *SPERM motility, *OLIGOSPERMIA, *OVUM, *FERTILIZATION in vitro, *REPRODUCTIVE technology

Abstract

Assisted reproductive technology (ART) has emerged as a crucial method in modern medicine for tackling infertility. However, the success of fertilization depends on the quality and quantity of sperm, often necessitating invasive surgical intervention, which presents challenges for non-invasive in vitro fertilization. Acoustic microfluidics technology has found widespread application across various biological contexts. In this paper, we propose to introduce a novel approach using asymmetric acoustic streaming generated by a single interdigital transducer (IDT) to enhance sperm concentration and improve fertilization in vitro, particularly in cases of moderate oligozoospermia. The concentration of particles increased approximately 6-fold in the central region after acoustic enrichment. Moreover, sperm motility was significantly improved without additional DNA fragmentation, and all the oocytes remained viable after 5 min of acoustic enrichment. Notably, acoustic enrichment accelerated fertilization and embryo development, leading to a higher fertilization rate and faster cleavage speed. Specifically, within 36 hours, the multiple-cell embryo ratio was significantly increased compared to the control group. This finding further validates the feasibility and non-invasiveness of acoustic enrichment for sperm fertilization in vitro. This work provides a promising tool for in vitro fertilization, holding significant implications for assisted reproduction. [ABSTRACT FROM AUTHOR]

Published

2024

5. The impact of non-isothermal adsorption of dissolved gas on drying of acoustically levitated slurry droplet.

Author

David Pour, Yehonatan, Krasovitov, Boris, Fominykh, Andrew, and Levy, Avi

Subjects

*GAS absorption & adsorption, *HEAT convection, *ACOUSTIC streaming, *SPRAY drying, *HEAT radiation & absorption

Abstract

AbstractIn this study, we developed a transient convective heat and mass transfer model of an acoustically levitated slurry droplet evaporating in an atmosphere of air, water vapor, and soluble gas. The advanced model considers the effects of acoustic streaming, forced convection, non-isothermal gas absorption, and adsorption of dissolved gas on the evaporation rate of a liquid droplet containing small active solid particles. Adsorption of dissolved in a droplet soluble gas by solid particles leads to decreased dissolved gas concentration in a liquid droplet. A reduction in dissolved gas concentration in a liquid droplet causes an increase in the mass flux of active soluble gas from a gaseous phase to a slurry droplet, which causes a rise in the heating effect of absorption and an increase in evaporation rate of a droplet. The heat effect of adsorption also intensifies the evaporation rate. It is shown that the time of porous shell formation is essentially shorter when solid particles in slurry droplets are active compared to inert particles. [ABSTRACT FROM AUTHOR]

Published

2024

6. Modulating Phase Constitution and Copper Microsegregation for FeCoNiCuAl High-Entropy Alloy by Optimized Ultrasonic Solidification.

Author

Wang, X., Wang, J. Y., Xiao, R. H., Zhai, W., and Wei, B.

Subjects

ACOUSTIC streaming, COPPER, DENDRITIC crystals, RATE of nucleation, GRAIN refinement

Abstract

The introduction of one-dimensional (1D), two-dimensional (2D), and three-dimensional (3D) ultrasounds into solidifying FeCoNiCuAl high-entropy alloy was efficiently optimized, which realized the maximum input of acoustic energy and the effective adjustment of the energy proportion between stable and transient cavitation effects. In addition to the ordinary advantage of grain refinement, the superiority of power ultrasound in modulating such Cu-containing high-entropy alloys with dendritic structures mainly lay in the significant regulation of phase volume fraction and the elimination of severe Cu element microsegregation. As the main energy transmission form under 1D ultrasound, stable cavitation slightly increased the nucleation rate of α and γ1 phases, which jointly contributed to suppressing the Cu solute enrichment from 41.6 to 36 at pct through the acoustic streaming during the subsequent growth of γ1 phase. When 2D and 3D ultrasounds were applied, the intensive transient cavitation dominated the solidification process. The induced local high undercooling resulted in the competitive nucleation and growth between α and γ1 phases, leading to the more than one order of magnitude reduction in their grain sizes and the significant rise of γ1 phase volume fraction from 13 up to 50 pct. Meanwhile, it strikingly reduced the final Cu content difference between these two phases from over 30 to around 3.8 at pct by decreasing the Cu composition in competitively formed γ1 nuclei. The above microstructure modification brought in excellent compressive property for 3D ultrasonically solidified alloy, whose strength and ductility were simultaneously enhanced by 27 and 24 pct. [ABSTRACT FROM AUTHOR]

Published

2024

7. Effect of ultrasonic field on pool boiling heat transfer to Al2O3 nanofluid on ribbed surfaces.

Author

Liu, Ping, Sang, Shiming, Hu, Lianghong, Liu, Guangfeng, and Wang, Weihua

Subjects

HEAT transfer coefficient, EBULLITION, ACOUSTIC streaming, HEAT flux, HEAT convection

Abstract

Nanofluid was frequent technique which solved microscale heat and mass transport problems to intensify pool boiling heat transfer. This paper had investigated the effect of nanofluid, ultrasonic field and ribs surfaces on cooperative heat transfer enhancement in pool boiling. A two-step method was applied to prepare Al2O3 nanofluids of different kinds of concentrations and diameters. Group experiments were examined the influences of nanofluid concentration and diameter, ultrasonic power and distance and rib surface type on heat transfer characteristics, respectively. The heat flux and convection heat transfer coefficient were used the performance parameters. The results showed that the concentration and diameter of the Al2O3 nanofluid effected the heat transfer performance on the pool boiling. The Al2O3 nanofluid with an average diameter of 80 nm had the most significant enhancement effect on the pool boiling heat transfer performance, but the Al2O3 with a diameter of 30 nm had the weakest enhancement effect, when the concentration of Al2O3 nanofluid was 0.01 wt%. Meanwhile, the generated acoustic streaming effect and cavitation effect by ultrasonic field can promote the energy accumulation, rupture and regeneration of the bubbles at low superheat stage on nanofluid pool boiling. The heat transfer coefficient (HTC) gradually enhances as the ultrasonic field changes. At an ultrasonic power of 528 W and a distance of 50 mm, the nanofluid pool boiling increased by 44.34% compared to no ultrasonic field HTC. Compared with No rib, the boiling point of the Al2O3 nanofluidic pool boiling of Rib II was reduced by 2°C under the ultrasonic field. The nanofluid pool boiling with ultrasonic field of p = 528 W and Rib II had the best heat transfer effect, and HTC improved more than 50%. This is due to the addition of more nucleation points for bubbles on the heated surface of the Rib II. [ABSTRACT FROM AUTHOR]

Published

2024

8. Auditory pallial regulation of the social behavior network.

Author

Spool, Jeremy A., Lally, Anna P., and Remage-Healey, Luke

Subjects

*ACOUSTIC streaming, *AUDITORY perception, *ZEBRA finch, *SOCIAL networks, *EMOTIONAL state, *HYPOTHALAMUS

Abstract

Sensory cues such as vocalizations contain important social information. Processing social features of vocalizations (e.g., vocalizer identity, emotional state) necessitates unpacking the complex sound streams in song or speech; this depends on circuits in pallial cortex. But whether and how this information is then transferred to limbic and hypothalamic regions remains a mystery. Here, using gregarious, vocal songbirds (female Zebra finches), we identify a prominent influence of the auditory pallium on one specific node of the Social Behavior Network, the lateral ventromedial nucleus of the hypothalamus (VMHl). Electrophysiological recordings revealed that social and non-social auditory stimuli elicited stimulus-specific spike trains that permitted stimulus differentiation in a large majority of VMHl single units, while transient disruption of auditory pallium elevated immediate early gene activity in VMHl. Descending functional connections such as these may be critical for the range of vertebrate species that rely on nuanced communication signals to guide social decision-making. A study in songbirds using site-directed pharmacology, immediate early gene labeling, and awake electrophysiology reveals a link between regions of the pallium critical for auditory processing and a specific node of the Social Behavior Network [ABSTRACT FROM AUTHOR]

Published

2024

9. Ultrasonic assisted electropolishing to reduce the surface roughness of laser powder bed fusion based additively manufactured copper heat exchanger components.

Author

Rahman, Md Hafizur, McCarroll, Angus, Siddaiah, Arpith, Kumar, Pankaj, and Menezes, Pradeep L.

Subjects

*COPPER surfaces, *ACOUSTIC streaming, *HEAT exchangers, *SURFACE roughness, *COPPER, *ABRASIVE machining

Abstract

As-built additively manufactured components for heat exchanger applications, suffer from high surface roughness. In this study, a novel ultrasonic-assisted electropolishing setup is designed and tested to reduce the internal surface roughness of a Laser Powder Bed Fusion (L-PBF) additively manufactured copper (GRCop-42) heat exchanger component. In the electropolishing setup, the surface of the as-built heat exchanger is used as the anode while a bulk copper rod is used as the cathode. An electropolishing fluid consisting of CuCl2, HCl, and SiC abrasive particles was used as electrolyte media, along with ultrasonication. The effect of chemical constituents, ultrasonic duration, and abrasive particles on surface roughness reduction was studied. It was observed that the ultrasonic agitation condition assisted with the abrasive particles was beneficial to reduce the surface roughness of the heat exchanger sample (over 50%) through acoustic streaming and scrubbing effect. An addition of 1% bio-based trihexyltetradecyl phosphonium saccharinate ionic liquid improved the corrosion properties for the copper surface. Overall, to reduce the roughness of L-PBF additively manufactured samples of complicated shapes with internal features, this process could be a viable technique, where mechanical polishing is not possible and internal surfaces are not accessible. [ABSTRACT FROM AUTHOR]

Published

2024

10. Sensory intelligence for extraction of abstract auditory rules from a speech sound stream in children with cochlear implants.

Author

He, Liu-Ting, Xu, Xin-Ran, Guan, Rui-Rui, Zhao, Wan, Sun, Jia-Qiang, Sun, Jing-Wu, and Guo, Xiao-Tao

Subjects

*SPEECH perception, *ACOUSTIC streaming, *AUDITORY perception, *SPACE perception, *COCHLEAR implants, *TONE (Phonetics)

Abstract

• Cochlear-implanted (CI) children have difficulty in extracting abstract auditory rules from a complex speech sound stream. • Sensory intelligence and everyday hearing abilities greatly vary in CI children and are closely related. • Sensory intelligence in speech may gradually develop during childhood and adolescence. Sensory intelligence in the brain helps listeners automatically extract abstract auditory rules formed by invariant acoustic features from complex speech sound streams, presumably serving as the neural basis for speech comprehension. However, whether this intelligence is deficient in children with cochlear implants (CIs) remains unclear. Mandarin Chinese monosyllables shared a flat lexical tone contour to form an abstract auditory rule but differed in other acoustic features to construct a complex speech sound stream. The abstract rule was occasionally violated by monosyllables with a rising or falling lexical tone. In normal hearing (NH) children, the abstract auditory rule could be extracted, as revealed by a mismatch negativity (MMN) and a late discriminative negativity (LDN). However, the MMN and LDN were only evoked in CI children with good hearing and speech performance. NH children with a higher speech perception or spatial hearing score had a greater MMN. The LDN was attenuated with increasing age in NH children. The sensory intelligence for extraction of auditory abstract rules, associated with speech perception, is deficient in CI children. This intelligence may gradually develop during childhood and adolescence. Deficient sensory intelligence in CI children may aid in understanding poor speech comprehension in complex environments. [ABSTRACT FROM AUTHOR]

Published

2024

11. Enhancement of acoustic cavitation streaming: A study on surface finishing of additively manufactured components.

Author

Medya, Saikat and Yeo, S.H.

Subjects

ACOUSTIC streaming, SURFACE finishing, PROCESS capability, SURFACE roughness, CAVITATION, CAVITATION erosion

Abstract

Due to the poor surface characteristics of additively manufactured parts, the necessity for post-process surface enhancement is crucial. Among the prevalent post-processing techniques, the acoustic cavitation-based surface finishing technique has recently emerged. Despite a considerable amount of focused research on the material removal mechanisms of this technique, less attention has been devoted to addressing its limitations associated with enhancing the process capability towards achieving a better surface finish. The driving force behind the acoustic cavitation technique is the bubble implosion through cavitation streaming, and the cessation of the acoustic cavitation streaming beyond a certain length is the main limitation. It has restrained the process capability towards finishing both external and internal surfaces. Hence, this research aims to unravel novel ways of employing the acoustic cavitation-generating parameters and achieving better-quality surface finishing of additively manufactured (AM) components. A study has been conducted on different AM materials, including Inconel 625 and aluminum alloy, by introducing various methods associated with acoustic amplitude, working mediums, temperature, and external vibration. The results reveal a significant reduction in average surface roughness for both materials. The topographical and morphological observations confirm the qualitative improvement on the surfaces. In addition, the conical bubble structures that frame the acoustic cavitation streaming are elucidated by implementing high-speed imaging techniques, and their enhancement at different parametric conditions is delineated. Henceforth, the findings suggest a notable insight into the potential of the employed approaches in enhancing the acoustic cavitation streaming for achieving a better surface finish of AM components. [Display omitted] • Surface finishing of AM components by enhanced acoustic cavitation. • Overcoming the limitations of acoustic cavitation for surface quality improvement. • Acoustic cavitation: factors affecting acoustic streaming and AM surface quality. • Thermal effect on bubble structures in free-field and confined acoustic cavitation. • A study on parametric investigation of acoustic cavitation: a different approach. [ABSTRACT FROM AUTHOR]

Published

2024

12. Ultrasounds Induced Microstructure Transition and Improved Mechanical Property of Directionally Solidified Ternary Cu–Al–Ni Alloy.

Author

Hu, Y. J., Wang, J. Y., Zhai, W., and Wei, B.

Subjects

ACOUSTIC streaming, COLUMNAR structure (Metallurgy), GRAIN refinement, TERNARY alloys, DIRECTIONAL solidification

Abstract

Two ultrasonic modes, i.e., continuous and pulsed ultrasounds, were introduced into the directional solidification process of Cu68.3Al27.6Ni4.1 alloy. A columnar-to-equiaxed structure transition occurred to primary β(Cu3Al) phase within continuous ultrasonic field, which was accompanied with a grain size reduction by 7.5 times. Under pulsed ultrasound, β phase maintained the fine columnar structures with a similar grain size. In the former case, numerous β phase nucleation sites formed ahead of solid/liquid (S/L) interface because of the large local undercoolings induced by transient cavitation. Meanwhile, intensive acoustic streaming suppressed the liquid temperature gradient from 120 to 85 K/cm, which interrupted the solute transportation along heat flow direction and resulted in equiaxed microstructures. Under the intermittent ultrasonic action in the latter case, fewer nucleation sites were generated near S/L interface but small columnar β grains were split from the original ones under stable cavitation. Since no steady convection was driven, the liquid temperature gradient of 110 K/cm remained almost constant, making those grains grow into refined columnar structures. Under the action of pulsed ultrasound, the yield strength was enhanced by a factor of 1.5 because of grain refinement strengthening, together with 94 pct shape recovery rate due to columnar grain structures. [ABSTRACT FROM AUTHOR]

Published

2024

13. Binge boxes.

Author

Zaluzny, Peter

Subjects

*AUDIO codec, *STREAMING video & television, *ACOUSTIC streaming, *SMART television devices, *COMPUTER performance

Abstract

The article discusses the continued relevance of streaming devices despite the availability of built-in streaming apps on modern TVs. It highlights reasons to consider purchasing a streaming device, such as updating older TVs, adding smart functions to offline devices, accessing more apps, and watching live TV. The article also compares dongles and boxes, providing key factors to consider when choosing a streaming device, such as app support, remote control, HDR support, and parental controls. [Extracted from the article]

Published

2024

14. SteelSeries Arena 3 speakers: Detail-rich sound for every game.

Author

BAYLEY, DOMINIC

Subjects

*ACOUSTIC streaming, *DIGITAL music, *AUDIO frequency, *USB technology, *TELEPHONE calls

Abstract

The SteelSeries Arena 3 is a 2.0 speaker system that offers clear and detailed sound, making it ideal for PC gaming. The speakers have a sleek all-black design with a shape reminiscent of Darth Vader's helmet. They come with a mix of wired and wireless connectivity options, including Bluetooth 4.2, and have simple controls for easy use. The speakers deliver immersive audio and can fill up a room at just 60 percent volume. While they lack USB-C connectivity and more RGB accents, they offer a versatile and high-quality sound experience for gamers and music enthusiasts. The SteelSeries Arena 3 is priced at $150. [Extracted from the article]

Published

2024

15. Physical field of dual-frequency ultrasonic vibration and its effect on solidification behavior of MgZnY alloy

Author

Zhaoyang Yin, Qichi Le, Liang Ren, Weiyang Zhou, Qiyu Liao, Shutang Gao, and Lei Bao

Subjects

Dual-frequency ultrasonic, Numerical simulation, Acoustic pressure, Acoustic streaming, Element distribution, Mining engineering. Metallurgy, TN1-997

Abstract

A three-dimensional model was established for coupled simulation of the physical field in a liquid subjected to dual-frequency ultrasonic vibration. The effect of sonotrode position, tip shape, and vessel on the distributions of acoustic pressure and acoustic streaming were clarified. The influence of physical fields on the solidification behavior of Mg alloy was investigated. The simulation results show that the interaction between the two ultrasounds was weakened as the sonotrode spacing increased, and the radiating angle had little effect on the acoustic pressure distribution. The volume mean pressure in the liquid radiated by the plane tip was the smallest, but with the greatest acoustic streaming intensity. In contrast, the spherical tip radiated the highest volume mean pressure in the liquid medium, but the acoustic streaming was severely suppressed. Attributed to the smooth spherical surface that facilitated fluid flow, high flow velocity could be achieved using a round-bottomed crucible without severe acoustic pressure attenuation. The experimental results show that cavitation and acoustic flow caused the coarse dendrites to turn into fine isometric crystals. The acoustic flow accelerated the melt flow and alleviated the segregation and precipitation of Zn elements, leading to a decrease in the content and size of the second phase in the billet.

Published

2024

16. Microstructure and mechanical properties of Cu–Cr–Zr–ZrB2 composites by novel fabrication process of ultrasonic vibration treatment

Author

Siruo Zhang, Guanglong Li, Yingdong Qu, Huijun Kang, Zongning Chen, Enyu Guo, Wei Zhang, and Tongmin Wang

Subjects

Copper matrix composites, In-situ reaction, Ultrasonic vibration treatment, Acoustic streaming, Acoustic cavitation, Mining engineering. Metallurgy, TN1-997

Abstract

Copper matrix composites with dual-scale particles were fabricated through casting with reaction. Ultrasonic vibration has been successfully introduced into the melt at about 1523 K while the microstructural development and mechanism of copper matrix composites with high-performance through a novel method of casting with ultrasonic vibration treatment are investigated. When ultrasonic vibration is applied, the distribution of micro-scale particles is greatly improved. Primary Cr phase convents to non-dendrite and large aggregates of ZrB2 particles are disrupted into small clusters because of acoustic cavitation and acoustic streaming. The ultimate tensile strength and elongation of Cu-1wt%Cr-0.3 wt%Zr-1wt%ZrB2 composite in as-cast state were 321 MPa and 14.37 %, recording a 28.4 % and 14 % increment respectively compared with the sample without treatment. After solution treatment, deformation and aging subsequently, the uniform distribution of reinforcements also decreases the average transverse grain thickness and increases the dislocation density which improve the comprehensive properties.

Published

2024

17. Sound absorption mechanism of sonic black hole with labyrinthine units and micro perforated panel.

Author

Liang, Xiao, Chu, Jiaming, Ouyang, Xiangjun, Yang, Qifu, Zhou, Zhuo, Liang, Haofeng, Yang, Zhen, Su, Liang, and Wang, Wenjie

Subjects

*ACOUSTIC excitation, *ACOUSTIC localization, *ACOUSTIC field, *ABSORPTION of sound, *WAVES (Fluid mechanics), *ACOUSTIC streaming, *SOUND energy

Abstract

Acoustic black hole (ABH) is a technique capable of manipulating the propagation of flexural wave, and the sonic black hole (SBH) is a kind of ABH which is used to manipulate sound wave in a fluid medium. In this paper, we propose an SBH structure with labyrinthine units and combine with micro-perforated panel (MPP) to form a composite sound absorption structure. The sound absorption mechanism of the absorption structure is deeply investigated using numerical and simulation methods. The simulation reveals the sound absorption mechanism by acoustic streaming effects of composite sound absorption structure. We analyze the flow characteristics of the acoustic medium under acoustic excitation, and the effect of the flow field on the distribution of the acoustic field, and the energy dissipation distribution. Our theoretical results show that the sound absorption is attributed to the effects of sound energy focusing of ABH, the local resonance of MPP, and the acoustic energy localization and dissipation effect of labyrinthine units caused by large flow velocity gradients. Finally, the proposed composite sound absorption structure has good sound absorption performance, which is also confirmed by impedance tube experiments. It can provide a new way of thinking for the design and optimization of the SBH structure. [ABSTRACT FROM AUTHOR]

Published

2024

18. MAV-Link-Based Control and Coordination of a Multi-Drone Cluster for Intelligence, Surveillance and Reconnaissance Tasks.

Author

Toma, Andrea, Cecchinato, Niccolò, Ferrin, Giovanni, Scagnetto, Ivan, Drioli, Carlo, and Foresti, Gian Luca

Subjects

*STREAMING video & television, *ACOUSTIC streaming, *TELECOMMUNICATION systems, *DRONE aircraft, *INTERNET usage monitoring

Abstract

Research on drone systems is expanding rapidly and finds application in many fields. These systems provide powerful and precise means in several domains from surveillance to agriculture. If we look inside a drone system, we will find several parts: the aerial vehicle(s), the onboard sensors, a computing device, and the autopilot, a communication network, a ground control station, control software, and a security module, encrypting commands and messages. In a multi-drone application, the system becomes more complex and coordination along with synchronization of the Unmanned Aerial Vehicles (UAVs) forms the strategic parts of the whole system. This manuscript focuses on an Intelligence, Surveillance and Reconnaissance (ISR) application and investigates a complete HW/SW architecture for a number of deployments where the secure control architecture is based on the MAVLink protocol for automatic control of the UAVs fully enabled by audio and video acquisition and processing. Indeed, one of the key features and novelties introduced by this proposal is the combined use of audio and video inputs, in order to provide a more precise and robust detection of targets and the related reaction of the system. The proposed system setup, user control scheme, ciphering and synchronization methods, and the related experiments are explored for laying the basis for future ideas and developments. [ABSTRACT FROM AUTHOR]

Published

2024

19. Combined effects of ultrasonic vibration and FeCoNiCrCu coating on interfacial microstructure and mechanical properties of Al/Mg bimetal by compound casting.

Author

Yuan-cai Xu, Wen-ming Jiang, Qing-qing Li, Ling-hui Yu, Xiao-peng Yu, and Zi-tian Fan

Subjects

*DIFFUSION coatings, *ACOUSTIC streaming, *LAMINATED metals, *ULTRASONIC effects, *EUTECTIC structure

Abstract

In this work, a new treatment method combining ultrasonic vibration with FeCoNiCrCu high entropy alloy (HEA) coating was used to prepared Al/Mg bimetal through the lost foam compound casting. The effects of composite treatment involving ultrasonic vibration and HEA coating on interfacial microstructure and mechanical properties of Al/Mg bimetal were studied. Results demonstrate that the interface thickness of the Al/Mg bimetal with composite treatment significantly decreases to only 26.99% of the thickness observed in the untreated Al/Mg bimetal. The HEA coating hinders the diffusion between Al and Mg, resulting the significant reduction in Al/Mg intermetallic compounds in the interface. The Al/Mg bimetal interface with composite treatment is composed of Al3Mg2 and Mg2Si/AlxFeCoNiCrCu+FeCoNiCrCu/δ-Mg+Al12Mg17 eutectic structures. The interface resulting from the composite treatment has a lower hardness than that without treatment. The acoustic cavitation and acoustic streaming effects generated by ultrasonic vibration promote the diffusion of Al elements within the HEA coating, resulting in a significant improvement in the metallurgical bonding quality on the Mg side. The fracture position shifts from the Mg side of the Al/Mg bimetal only with HEA coating to the Al side with composite treatment. The shear strength of the Al/Mg bimetal increases from 32.16 MPa without treatment to 63.44 MPa with ultrasonic vibration and HEA coating, increasing by 97.26%. [ABSTRACT FROM AUTHOR]

Published

2024

20. Cohesive strength of plasma sprayed Ni-10wt.%Al coatings enhanced by ultrasonic and depended on the power density.

Author

Liu, Huiqiang, Wang, Haibo, Wang, Jichun, Gao, Pengfei, Han, Guofeng, Wang, Xiaoming, and Yang, Baijun

Subjects

*ACOUSTIC streaming, *PLASMA spraying, *SOUND pressure, *ULTRASONIC effects, *SURFACES (Technology), *PLASMA sprayed coatings, *CAVITATION erosion

Abstract

Plasma spray is a promising technology for surface protection and modification in many industrial application fields. However, the low adhesive or cohesive strength of the plasma sprayed coatings limited their further application. The cohesive strength was enhanced 115% ultra-sonicating the substrate during the plasma spraying process of Ni-10wt.%Al coatings. With the increase of power density from 0 to 1.32 W/cm2, the porosity, residual stress and strain were all decreased. However, when the power was further increased to 2.20 W/cm2, the porosity, residual stress and strain were all increased. Ultrasonic energy and the ultrasonic effects of acoustic pressure, acoustic streaming, heat effect, and cavitation effect would affect the physical processes of wetting, filling and solidification of the molten droplets during the plasma spraying process, affecting the microstructure and cohesive strength of the plasma sprayed coatings. The ultrasonic energy and ultrasonic effects which are affected by the ultrasonic power density affecting the fundamental physical processes is the key to enhance the cohesive strength of the plasma sprayed coatings. [ABSTRACT FROM AUTHOR]

Published

2024

21. Open-Set Recognition of Pansori Rhythm Patterns Based on Audio Segmentation.

Author

You, Jie and Lee, Joonwhoan

Subjects

MUSICAL form, ACOUSTIC streaming, POPULAR music genres, MUSICAL interpretation, RHYTHM, DEEP learning

Abstract

Pansori, a traditional Korean form of musical storytelling, is characterized by performances involving a vocalist and a drummer. It is well-known for the singer's expressive narrative (aniri) and delicate gesture with fan in hand. The classical Pansori repertoires mostly tell love, satire, and humor, as well as some social lessons. These performances, which can extend from three to five hours, necessitate that the vocalist adheres to precise rhythmic structures. The distinctive rhythms of Pansori are crucial for conveying both the narrative and musical expression effectively. This paper explores the challenge of open-set recognition, aiming to efficiently identify unknown Pansori rhythm patterns while applying the methodology to diverse acoustic datasets, such as sound events and genres. We propose a lightweight deep learning-based encoder–decoder segmentation model, which employs a 2-D log-Mel spectrogram as input for the encoder and produces a frame-based 1-D decision along the temporal axis. This segmentation approach, processing 2-D inputs to classify frame-wise rhythm patterns, proves effective in detecting unknown patterns within time-varying sound streams encountered in daily life. Throughout the training phase, both center and supervised contrastive losses, along with cross-entropy loss, are minimized. This strategy aimed to create a compact cluster structure within the feature space for known classes, thereby facilitating the recognition of unknown rhythm patterns by allocating ample space for their placement within the embedded feature space. Comprehensive experiments utilizing various datasets—including Pansori rhythm patterns (91.8%), synthetic datasets of instrument sounds (95.1%), music genres (76.9%), and sound datasets from DCASE challenges (73.0%)—demonstrate the efficacy of our proposed method to detect unknown events, as evidenced by the AUROC metrics. [ABSTRACT FROM AUTHOR]

Published

2024

22. Evaluating impedance boundary conditions to model interfacial dynamics in acoustofluidics.

Author

Kshetri, Khemraj Gautam and Nama, Nitesh

Subjects

*INTERFACE dynamics, *ACOUSTIC radiation force, *ACOUSTIC field, *SOUND waves, *PARTICLE dynamics, *ACOUSTIC streaming

Abstract

We present a numerical study to investigate the efficacy of impedance boundary conditions in capturing the interfacial dynamics of a particle subjected to an acoustic field and study the concomitant time-averaged acoustic streaming and radiation force fields. While impedance boundary conditions have been utilized to represent fluid–solid interface in acoustofluidics, such models assume the solid material to be locally reactive to the acoustic waves. However, there is a limited understanding of when this assumption holds true, raising concerns about the suitability of impedance boundary conditions. Here, we systematically investigate the applicability of impedance boundary conditions by comparing the predictions of an impedance boundary approach against a fully coupled fluid–solid model. We contrast the oscillation profiles of the fluid–solid interface predicted by the two models. We consider different scatterer materials to identify the extent to which the differences in interfacial dynamics impact the time-averaged fields and highlight the divergence within the predictions of the two models. Our findings indicate that, although impedance boundary conditions can yield qualitatively similar results to the full model in certain situations, the predictions from the two models generally differ both qualitatively and quantitatively. These results underscore the importance of exercising caution when applying these boundary conditions to model general acoustofluidic systems. [ABSTRACT FROM AUTHOR]

Published

2024

23. Remote self-testing for adult cochlear implant users: the effect of wireless streaming on speech recognition in noise.

Author

Rootlieb, Jasmijn M., Polspoel, Sigrid, Brienesse, Patrick, and Smits, Cas

Subjects

*ACOUSTIC streaming, *AUDIOMETRY, *SPEECH perception, *REPEATED measures design, *COCHLEAR nucleus

Abstract

AbstractObjectivesDesignStudy SampleResultsConclusionsWireless sound transfer methods for cochlear implant sound processors have become popular for remote self-assessed hearing tests. The aim of this study was to determine (1) spectral differences in stimuli between different wireless sound transfer options and (2) the effect on outcomes of speech recognition tests in noise.In study 1, the frequency response of different streaming options (Phonak Roger Select, Cochlear Mini Mic 2+, telecoil and Bluetooth connection) was measured by connecting headphones to CI sound processors. Study 2 followed a repeated measures design in which digits-in-noise (DIN) tests were performed using wireless streaming to sound processors from Cochlear, Advanced Bionics, and MED-EL.20 normal hearing participants.Differences in frequency response between loudspeaker and wireless streaming conditions were minimal. We did not find significant difference in DIN outcome (F4,194 = 1.062, p = 0.376) between the wireless transfer options with the Cochlear Nucleus 7 processor. No significant difference in DIN outcomes was found between Bluetooth streaming and the loudspeaker condition for all of the three tested brands. The mean standard error of measurement was 0.72 dB.No significant differences in DIN test outcomes between wireless sound transfer and the reference method were found. [ABSTRACT FROM AUTHOR]

Published

2024

24. Cell integrity maintenance and genetic transfection of protoplasts in an acoustofluidic system.

Author

Shen, Xiaotian, Zhang, Jieyi, Zhang, Tianjiao, Wang, Shuaiqi, Han, Ziyu, Wang, Jiehua, and Duan, Xuexin

Subjects

*HEMICELLULOSE, *PROTOPLASTS, *CELLULAR mechanics, *PLANT plasma membranes, *ACOUSTIC streaming, *CELL anatomy, *CELL culture

Abstract

Hydrodynamic force loading platforms based on acoustofluidics have been developed to study the mechanical deformation of cancer cells and to control cell behavior. However, so far there have been no experimental measurements on living plant cells using such an acoustic approach. Unique structures, including cell walls, allow plant cells to exhibit more variation in mechanical resistance. In this work, we analyzed plant cell deformation and membrane permeability using a gigahertz (GHz) acoustofluidic system. By recording the proportion of intact cells in the cell population, we evaluated the mechanical resistance of the protoplasts to the hydrodynamic forces of the acoustic streaming. The results showed that a regenerated primary cell wall (PCW) could significantly improve the mechanical resistance of individual plant cells within 24 h compared to the freshly prepared protoplasts without walls. The results of enzymatic degradation showed that three main components of the primary cell wall contribute to different degrees to the improvement of the mechanical properties of the cells, in decreasing order: cellulose, hemicellulose, and pectin. Furthermore, we have shown that such an acoustofluidic system can alter the permeability of the protoplast membrane in a controllable manner for transient gene expression. [ABSTRACT FROM AUTHOR]

Published

2024

25. Noises on—How the Brain Deals with Acoustic Noise.

Author

de Hoz, Livia and McAlpine, David

Subjects

*ACOUSTIC streaming, *INFERIOR colliculus, *AUDITORY cortex, *STATISTICAL learning, *SOUND mixers & mixing, *EAR

Abstract

Simple Summary: The listening brain must resolve the mix of sounds that reaches our ears into events, sources, and meanings. In this process, noise—sound that interferes with our ability to detect or understand sounds we need or wish to—is the primary challenge when listening. Importantly, noise to one person, or in one moment, might be an important sound to another, or in the next. Despite the many challenges posed by noise, however, human listeners generally outperform even the most sophisticated listening technologies in noisy listening environments. Because extracting noise from the sound stream is a fundamental process in listening, understanding how the brain deals with noise, in its many facets, is essential to understanding listening itself. Here, we explore what it is that the brain treats as noise and how it is processed. We conclude that the brain has multiple mechanisms for detecting and filtering out noise, and that incorporating cortico-subcortical 'listening loops' into our studies is essential to understanding this early segregation between noise and signal streams. What is noise? When does a sound form part of the acoustic background and when might it come to our attention as part of the foreground? Our brain seems to filter out irrelevant sounds in a seemingly effortless process, but how this is achieved remains opaque and, to date, unparalleled by any algorithm. In this review, we discuss how noise can be both background and foreground, depending on what a listener/brain is trying to achieve. We do so by addressing questions concerning the brain's potential bias to interpret certain sounds as part of the background, the extent to which the interpretation of sounds depends on the context in which they are heard, as well as their ethological relevance, task-dependence, and a listener's overall mental state. We explore these questions with specific regard to the implicit, or statistical, learning of sounds and the role of feedback loops between cortical and subcortical auditory structures. [ABSTRACT FROM AUTHOR]

Published

2024

26. Progress of MEMS acoustic emission sensor: a review.

Author

Zhang, Junhui, Zhang, Sai, Yang, Yuhua, and Zhang, Wendong

Subjects

*COMPLEMENTARY metal oxide semiconductors, *ACOUSTIC emission, *ACOUSTIC signal detection, *ACOUSTIC streaming, *COINTEGRATION, *MICROELECTROMECHANICAL systems

Abstract

Purpose: Based on the micro-electro-mechanical system (MEMS) technology, acoustic emission sensors have gained popularity owing to their small size, consistency, affordability and easy integration. This study aims to provide direction for the advancement of MEMS acoustic emission sensors and predict their future potential for structural health detection of microprecision instruments. Design/methodology/approach: This paper summarizes the recent research progress of three MEMS acoustic emission sensors, compares their individual strengths and weaknesses, analyzes their research focus and predicts their development trend in the future. Findings: Piezoresistive, piezoelectric and capacitive MEMS acoustic emission sensors are the three main streams of MEMS acoustic emission sensors, which have their own advantages and disadvantages. The existing research has not been applied in practice, and MEMS acoustic emission sensor still needs further research in the aspects of wide frequency/high sensitivity, good robustness and integration with complementary metal oxide semiconductor. MEMS acoustic emission sensor has great development potential. Originality/value: In this paper, the existing research achievements of MEMS acoustic emission sensors are described systematically, and the further development direction of MEMS acoustic emission sensors in the future research field is pointed out. It provides an important reference value for the actual weak acoustic emission signal detection in narrow structures. [ABSTRACT FROM AUTHOR]

Published

2024

27. Research on the hydraulic parameters and leak rate of natural gas flow in natural gas pipelines based on the methods of characteristic line and successive approximation.

Author

Hou, Qingmin, Xiao, Guanghua, Xu, Fangmin, and Eddine, Hassan Nasser

Subjects

*NATURAL gas pipelines, *NATURAL gas, *GAS flow, *DIFFERENCE equations, *ACOUSTIC streaming, *CONSERVATION laws (Physics), *HYDRAULICS

Abstract

Pressure and flow rate are the most important hydraulic parameters in natural gas pipeline flow, and leak rate is the most crucial parameter after a leak accident occurs. The study of these parameters is vital to the safey of natural gas pipelines and risk assessment after accidents. In this research, based on the conservation laws universally applicable to the motion of objects, we establish the fundamental control equation group for natural gas flow. Then, for both normal and leak conditions of pipelines, we use the characteristic line method to derive the corresponding difference equations for the fundamental control equations, thereby providing calculation methods for pressure and flow rate. Finally, we investigate the calculation method of natural gas pipeline leak rate under different leak aperture sizes, and validate the accuracy of this method through simulation examples. [ABSTRACT FROM AUTHOR]

Published

2024

28. Suppression of short-range exposure to infectious aerosols using multiple paths of midair ultrasound acoustic streaming.

Author

Nagata, Kouta and Hasegawa, Keisuke

Subjects

*ACOUSTIC streaming, *AEROSOLS, *RESPIRATORY diseases, *PHASED array antennas, *AIR flow

Abstract

One of the major infectious routes of respiratory diseases, such as COVID-19, is exposure to viral aerosols transmitted from an infected person over a short distance. Conventionally, plastic shields or personalized ventilation methods utilizing fans or jets to generate airflows between two facing users have been used to combat such short-range infection. Nevertheless, these methods entail several drawbacks: bulky apparatus hindering users' cooperative activities must be placed between them, the shields need frequent cleaning and block conversation voices, and the jet- or fan-based methods yield uncomfortably strong airflows hitting the user's face. Here, a new airflow-based strategy for suppressing aerosol exposure, which overcomes all the above inconveniences, was proposed. In this strategy, ultrasound-driven localized airflows called acoustic streaming, whose positions and traveling directions can be electronically controlled, was used. A prototype system composed of a group of phased arrays of airborne ultrasound transducers was created, and they were set behind the users to redirect paths of aerosols emitted from the user's mouth toward their upper and back sides. It is experimentally confirmed that the proposed system could reduce exposure to aerosols whose diameters are the same as ones emitted from people by 89.95% under a certain setup. By controlling the position and direction of the streaming, the proposed method can maintain its performance when users move their heads or bodies. The proposed system can virtually produce or delete programmable partitions in the air as desired, and can be integrated with other conventional methods for infection control. [ABSTRACT FROM AUTHOR]

Published

2024

29. Nano droplet behaviour on vibrating surfaces: atomistic simulations for bio-NEMS/MEMS applications.

Author

Kumar, Mukesh, Tamang, Santosh Kumar, Owhal, Ayush, Roy, Tribeni, and Dabi, M.

Subjects

*ACOUSTIC surface waves, *MOLECULAR dynamics, *ACOUSTIC streaming, *NANOELECTROMECHANICAL systems, *TISSUE engineering, *RESEARCH personnel

Abstract

Recent advancement in nanoengineered technologies that use surface acoustic waves of variable frequency and amplitude have sparked significant interest among researchers in the field of bio nano electromechanical systems (Bio-NEMS/MEMS). The increased fascination with vibrating surfaces due to their acoustic streaming possibilities, is the driving force behind this research. These surfaces have outstanding physiochemical characteristics that make them extremely adaptable for a variety of applications, including fluidics, tissue engineering, targeted drug delivery, enhanced oil recovery, etc. In the present work, the study of the vibrating nano platinum surface has been carried out to analyze the effect of surface wettability, resistance force, and mean square displacements to obtain the desired performance using molecular dynamics simulations (MDS). A modified Lennard-Jones (LJ) potential was used to control the mobility of water molecules using a solid–liquid. The optimum performance of the nano surface for the desired application is obtained at higher amplitude (5 Å) and frequency (300 GHz) respectively. The average resistance force (FR) for high configuration surface vibrations increased to 80.14% i.e. from 4.4394 × 1014 kJ/mol/m, compared to 8.818 × 1013 kJ/mol/m at amplitude (2 Å) and frequency (50 GHz) configuration. This shows that the present work has substantial implications for applications towards nano technologies. [ABSTRACT FROM AUTHOR]

Published

2024

30. Analysis of Flow-induced Noise Characteristics of Ethylene Cracking Furnace Tubes before and after Coking.

Author

Zhou, F. Q., Zhao, S. Y., Zhang, S. J., Zhang, Y., Fu, S. C., and Yu, S. Q.

Subjects

COKE (Coal product), FURNACES, ACOUSTIC radiators, TUBES, SOUND pressure, ACOUSTIC streaming

Abstract

This paper presents a comprehensive investigation of flow-induced noise characteristics in ethylene cracking furnace tubes, covering both pre- and postcoking conditions. Large-eddy simulation (LES) was employed in conjunction with a generalized Lighthill's acoustic analogy model. The results indicate that noise sources can be classified as dipole acoustic sources, with energy primarily concentrated ranged from 300 to 1500 Hz, in comparison to standard conditions. The primary location of the acoustic source was identified in the region commonly referred to as the "necking" of the furnace tube, demonstrating a strong correlation with turbulence intensity near the tube wall. As the coke layer thickness in the furnace tube increased from 5 mm to 15 mm, both the sound power level and turbulence intensity exhibited significant growth. Specifically, the sound power level increased by 60.5% while the turbulence intensity increased by 58.5%. Variations in the overall sound pressure level (OASPL) curve measured within the tube could be utilized to assess coking levels. Significant peaks in the OASPL curve were observed as the furnace tube underwent substantial coking, with coke layer thicknesses of 10 mm and 15 mm. The corresponding OASPL values recorded were 79.25 dB and 119.08 dB, respectively. The findings of this work offer significant insights that may contribute to enhanced safety measures in the operation of ethylene cracking furnace tubes. [ABSTRACT FROM AUTHOR]

Published

2024

31. Characterizing Acoustic Behavior of Silicon Microchannels Separated by a Porous Wall.

Author

Hashemiesfahan, Mehrnaz, Christiaens, Jo Wim, Maisto, Antonio, Gelin, Pierre, Gardeniers, Han, and De Malsche, Wim

Subjects

ACOUSTIC streaming, MASS transfer, STREAMFLOW, STANDING waves, SOUND waves, PIEZOELECTRIC transducers

Abstract

Lateral flow membrane microdevices are widely used for chromatographic separation processes and diagnostics. The separation performance of microfluidic lateral membrane devices is determined by mass transfer limitations in the membrane, and in the liquid phase, mass transfer resistance is dependent on the channel dimensions and transport properties of the species separated by the membrane. We present a novel approach based on an active bulk acoustic wave (BAW) mixing method to enhance lateral transport in micromachined silicon devices. BAWs have been previously applied in channels for mixing and trapping cells and particles in single channels, but this is, to the best of our knowledge, the first instance of their application in membrane devices. Our findings demonstrate that optimal resonance is achieved with minimal influence of the pore configuration on the average lateral flow. This has practical implications for the design of microfluidic devices, as the channels connected through porous walls under the acoustic streaming act as 760 µm-wide channels rather than two 375 µm-wide channels in the context of matching the standing pressure wave criteria of the piezoelectric transducer. However, the roughness of the microchannel walls does seem to play a significant role in mixing. A roughened (black silicon) wall results in a threefold increase in average streaming flow in BAW mode, suggesting potential avenues for further optimization. [ABSTRACT FROM AUTHOR]

Published

2024

32. Influence of spraying power on microstructure and wear resistance of plasma spray Ni-10 wt. %Al coatings with a sound vibration.

Author

Wang, Jichun, Wang, Haibo, Mu, Xunxun, Ma, Xixi, Qian, Jiaming, and Gao, Pengfei

Subjects

PLASMA sprayed coatings, WEAR resistance, PLASMA spraying, ACOUSTIC streaming, SURFACE coatings, SOUND pressure, MICROSTRUCTURE

Abstract

The effect of spraying power on the microstructure and wear resistance of Ni-10 wt. %Al coating plasma sprayed with a 500 Hz sound vibration has been investigated. With the application of sound vibration, the compactness, cohesive bonding strength, and wear resistance of the coatings are all much higher. Meanwhile, with the increase of spraying power, the enhancement degree of the compactness, cohesive bonding strength, and wear resistance of the coatings are all increased. The sound vibration effects, which contain sound pressure, acoustic streaming, and heat effect, on the molten droplets are increased for their increasing melting induced by increasing spraying power. The wetting, flowing, and solidification of the molten droplets are all affected. Better wetting and flowing of the molten droplets promote their bonding on the surface of substrates and the solidified molten droplets, and their filling in the gaps of the solidified droplets. [ABSTRACT FROM AUTHOR]

Published

2024

33. Emotion Recognition from Videos Using Multimodal Large Language Models.

Author

Vaiani, Lorenzo, Cagliero, Luca, and Garza, Paolo

Subjects

LANGUAGE models, EMOTION recognition, EMOTIONS, ACOUSTIC streaming, TRANSFORMER models

Abstract

The diffusion of Multimodal Large Language Models (MLLMs) has opened new research directions in the context of video content understanding and classification. Emotion recognition from videos aims to automatically detect human emotions such as anxiety and fear. It requires deeply elaborating multiple data modalities, including acoustic and visual streams. State-of-the-art approaches leverage transformer-based architectures to combine multimodal sources. However, the impressive performance of MLLMs in content retrieval and generation offers new opportunities to extend the capabilities of existing emotion recognizers. This paper explores the performance of MLLMs in the emotion recognition task in a zero-shot learning setting. Furthermore, it presents a state-of-the-art architecture extension based on MLLM content reformulation. The performance achieved on the Hume-Reaction benchmark shows that MLLMs are still unable to outperform the state-of-the-art average performance but, notably, are more effective than traditional transformers in recognizing emotions with an intensity that deviates from the average of the samples. [ABSTRACT FROM AUTHOR]

Published

2024

34. Cutting behaviors of cortical bone ultrasonic vibration-assisted cutting immersed in physiological saline

Author

Peng Gao, Zhiyu Xu, Xinlong Zhao, Shengqi Li, Min Wang, Linkai Jing, and Tao Zan

Subjects

Ultrasonic vibration-assisted cutting, Bone saline immersed cutting, Ultrasonic cavitation, Surface damage, Acoustic streaming, Chemistry, QD1-999, Acoustics. Sound, QC221-246

Abstract

In orthopedic surgery, cortical bone cutting usually involves washing and cooling with physiological saline. However, how the saline changes the cutting behaviors of bone ultrasonic vibration cutting remains challenging. Hence, this paper simulates the clinical ultrasonic cutting condition in orthopedics to reveal the cutting behaviors of bone ultrasonic vibration orthogonal cutting immersed in physiological saline. The dynamic equation and motion process curves of ultrasonic cavitation bubbles were established. The results showed that the bone cutting immersed in physiological saline significantly improved the surface quality, reduced surface roughness and mechanical damage, and avoided large brittle cracks propagation. In saline immersed cutting, the physiological saline changes the mechanical behaviors of bone materials, resulting in plastic behaviors for the material removal and crack deflection. This study establishes the influence of physiological saline on the ultrasonic vibration cutting performance, providing guidance for orthopedic bone cutting surgery methods.

Published

2024

35. Study of liquid-phase mass transfer and residual stress in jet electrodeposition process with coaxial megasonic agitation

Author

Ke Zhai, Feng Zhou, Yifan Wang, Shihao Ma, Lide Fang, and Liqun Du

Subjects

Megasonic agitation, Mass transfer coefficient, Residual stress, Acoustic streaming, Jet electrodeposition, Chemistry, QD1-999, Acoustics. Sound, QC221-246

Abstract

The electrodeposition process confronts significant challenges arising from mass transfer limitation and residual stress. To address these issues, an innovative method, combining megasonic agitation with coaxial jet electrodeposition, is introduced. This approach aims to enhance mass transfer and mitigate residual stress. First, an electrodeposition nozzle device was designed, and the liquid-phase mass transfer during electrodeposition was analyzed through finite element simulation. Simulation results indicate that the mass transfer coefficient increases with rising megasonic power density. Notably, when the megasonic power density reached 20 W/cm2, the mass transfer coefficient increased from 0.45 × 10−7 m/s to 18.63 × 10−7 m/s, compared to electrodeposition without megasonic agitation. Secondly, electrodeposition experiments were conducted both with and without megasonic assistance. X-ray diffraction (XRD) was employed to measure the residual stress values of the electrodeposited layers. The results reveal that samples processed with megasonic assistance exhibit lower residual stress values compared to those without. Specifically, at a megasonic power density of 10 W/cm2, the residual stress was 94.3 MPa, representing a 37.7 % reduction compared to the residual stress of 151.5 MPa observed in samples without megasonic agitation. Overall, the findings demonstrate that coaxial megasonic agitation can effectively enhance the liquid-phase mass transfer capability during electrodeposition and reduce the residual stress of the electroplated layer. This innovative method presents a promising avenue for improving electrodeposition processes and achieving superior material properties.

Published

2024

36. Multiple ultrasounds assisted phase separation and monotectic solidification of liquid ternary Al81.5Cu14.7Bi3.8 immiscible alloy.

Author

Wu, Wenhua, Wang, Dongzhen, Zhai, Wei, Wang, Jianyuan, and Wei, Bingbo

Subjects

*PHASE separation, *ACOUSTIC streaming, *PHASE transitions, *ULTRASONIC imaging, *ACOUSTIC transients, *LIQUID alloys, *HYPEREUTECTIC alloys

Abstract

Multiple power ultrasounds were employed to investigate the phase transition process of ternary Al81.5Cu14.7Bi3.8 immiscible alloy by various exerting modes. As the ultrasonic sources increased, the liquid phase separation pattern transformed from (Bi)-rich layered macrosegregation into the uniform distribution of secondary (Bi) droplets. Meanwhile, the primary (Al) phase evolved from coarse dendrites into plenty of small spherical grains and also tended to be uniformly dispersed. The subsequently formed ternary (Al) + (Al2Cu) + (Bi) monotectic structure, featured by the alternative (Al) and (Al2Cu) lamellar structure with fine (Bi) grains distributed, was coarsened first and then refined. Numerical simulations showed that the transient cavitation and the acoustic streaming strength were significantly enhanced by increasing ultrasonic beams, with the fourfold ultrasounds producing the most prominent effects on the phase separation process. The intensive and enlarged cavitation areas greatly accelerated the nucleation of both the secondary liquid phase and primary solid phase, which refined the growing (Bi) droplets and (Al) dendrites. The strength and morphology of acoustic streaming were the key factors in offsetting Stokes motion and carrying the growing grains to various regions, resulting in a uniform microstructure. Furthermore, increasing ultrasonic sources improved the friction and wear properties of the solidified alloy, which indicated that the Al81.5Cu14.7Bi3.8 immiscible alloy may become an excellent wear-resistant material owing to the uniform monotectic structure fabricated by the fourfold ultrasounds. [ABSTRACT FROM AUTHOR]

Published

2023

37. Integration of Localized Surface Plasmon Resonance Sensor on Surface Acoustic Wave Device

Author

Kida, Atsuya, Kondoh, Jun, Kacprzyk, Janusz, Series Editor, Gomide, Fernando, Advisory Editor, Kaynak, Okyay, Advisory Editor, Liu, Derong, Advisory Editor, Pedrycz, Witold, Advisory Editor, Polycarpou, Marios M., Advisory Editor, Rudas, Imre J., Advisory Editor, Wang, Jun, Advisory Editor, Ono, Yukinori, editor, and Kondoh, Jun, editor

Published

2024

38. Classic Sound with Streaming Smarts.

Author

Kumin, Daniel

Subjects

*ACOUSTIC streaming, *SMART television devices, *HEADPHONES, *AUDIO amplifiers, *SIGNAL processing, *DRUM set, *RADIO frequency modulation, *DIGITAL music

Abstract

The article discusses Technics' new SU-GX70 Network Audio Amplifier, which combines integrated amplification with streaming capabilities. The amplifier features high-tech components such as a JENO amplifier and a room-EQ system. It also includes a built-in FM tuner and offers various connectivity options. The author describes the sound quality as pristine and dynamic, although they note that the amplifier may lack power for larger rooms. The article also mentions Technics' Audio Center app, which provides additional functionality for controlling the amplifier. Overall, the Technics SU-GX70 is praised for its high-end sound quality and sleek design, but it may not be suitable for all speakers and larger rooms. [Extracted from the article]

Published

2024

39. Rotational acoustofluidic fields induced by cross structures with asymmetric radiation surface arrangements.

Author

Tang, Qiang, Tang, Shuai, Liu, Pengzhan, Gu, Zhouzhi, and Xu, Zhaomei

Subjects

*ACOUSTIC streaming, *ASTROPHYSICAL radiation, *RADIATION, *SIGNAL generators, *OBJECT manipulation

Abstract

In this study, a novel strategy to generate sophisticated acoustic streaming vortices, which would be available for rotational manipulation of micro-/nano-scale objects, is proposed and simulated. All structural units in the microfluidic chamber are symmetric in design, and all radiation surfaces have the same settings of input frequency, oscillation amplitude, and initial phase. Different kinds of asymmetric acoustofluidic patterns can be generated in the originally static microfluidic chamber only because of the asymmetric arrangement of multiple radiation surfaces in space. The calculation results of kaleidoscopic acoustofluidic fields together with particle movement trajectories induced by cross structures with different radiation surface distributions further demonstrate the versatile particle manipulation capabilities of these functional microfluidic devices. In comparison to the existing oscillation modulation method, which requires multiple radiation surfaces with different initial phases, acoustofluidic devices with a same initial phase of all radiation surfaces can significantly reduce the required number of auxiliary signal generators and power amplifiers. The proposed generation method of acoustofluidic patterns is promising for microfluidic mixing without rotating machinery, driving operation of microrobots, and rotational manipulation of biological samples. [ABSTRACT FROM AUTHOR]

Published

2022

40. Acoustophoresis-driven particle focusing and separation with standard/inverse Chladni patterns.

Author

Xiong Zhao and Nanjing Hao

Subjects

*ACOUSTIC radiation force, *ACOUSTIC streaming, *ACOUSTIC excitation, *PARTICLE motion, *ACOUSTICS, *MICROFLUIDICS

Abstract

Manipulating objects with acoustics has been developed for hundreds of years since Chladni patterns in gaseous environments were exhibited. In recent decades, acoustic manipulation in microfluidics, known as acoustofluidics, has rapidly thrived and many sophisticated technologies were born. However, the basic background motion of particles under acoustic excitation is usually neglected and the classical Chladni patterns haven't been reproduced in an aqueous environment. In this study, we investigated the basic mechanism and the motion of suspended particles and sinking particles in a plain microchamber under low-frequency excitation (3-5 kHz). The mechanisms were clearly distinguished by comparing the differences among colored fluids, suspended particles, and sinking particles. The suspended particles rotated around the antinode with a speed up to 55.1 µm s-1 at 100 Vpp by the acoustic streaming and they approached each other by the secondary acoustic radiation force. The sinking particles concentrated at the node with a speed up to 22.3 µm s-1 at 100 Vpp by bouncing on the vibrating surface and the primary acoustic radiation force. We have reproduced the classical standard/inverse Chladni patterns in an aqueous environment for the first time, and they were leveraged to separate SiO2 particles with different sizes. The big particles with an average diameter of 9.68 µm were concentrated at the node while the small particles with an average diameter of 2.72 µm were collected at the antinode within 2 min. These results not only provide insightful perspectives of basic mechanisms, but also open up new possibilities for advanced acoustic tweezers. [ABSTRACT FROM AUTHOR]

Published

2024

41. Thermoacoustic Modeling of Cryogenic Hydrogen.

Author

Matveev, Konstantin I. and Leachman, Jacob W.

Subjects

*COMPUTATIONAL fluid dynamics, *HYDROGEN, *THERMOPHYSICAL properties, *WORKING fluids, *ACOUSTIC streaming

Abstract

Future thermoacoustic cryocoolers employing hydrogen as a working fluid can reduce reliance on helium and improve hydrogen liquefaction processes. Traditional thermoacoustic modeling methods often assume ideal-gas thermophysical properties and neglect finite-amplitude effects. However, these assumptions are no longer valid for hydrogen near saturated states. In this study, a comparison between the results of computational fluid dynamics simulations using actual hydrogen properties and a low-amplitude, ideal-gas thermoacoustic theory was carried out in a canonical plate-based stack configuration at a mean pressure of 5 bar. It was found that the simplified analytical theory significantly underpredicts the cooling power of hydrogen-filled thermoacoustic setups, especially at lower temperatures in high-amplitude, traveling-wave arrangements. In addition, a thermoacoustic prime mover was modeled at higher temperatures, demonstrating very close agreement with the ideal-gas-based theory. The CFD approach is recommended for the design of future hydrogen-based cryocoolers at temperatures below 80 K. [ABSTRACT FROM AUTHOR]

Published

2024

42. The Design and Investigation of Hybrid a Microfluidic Micromixer.

Author

Waqas, Muhammad, Janusas, Giedrius, Naginevičius, Vytenis, and Palevicius, Arvydas

Subjects

ACOUSTIC streaming, REYNOLDS number, HYBRID systems, FLUID flow, SOUND pressure, SPEED of sound, MICROFLUIDICS, MICROCHANNEL flow

Abstract

Today, microfluidics has become a revolutionary interdisciplinary topic with considerable attention in a wide range of biotechnology applications. In this research work, a numerical investigation of a microfluidic micromixer is carried out using a hybrid actuation approach with different micropillar shapes and gaps. For this purpose, COMSOL Multiphysics v.5.2. is used with three different physics, such as thermoviscous acoustic physics to solve acoustic governing equations, laminar physics to solve fluid flow governing equations, and diluted transport species to solve mixing governing equations. The simulations were carried out at different Reynolds numbers such as 2, 4, 6, 8, 10, and 12 with an oscillation frequency of 15 kHz. The results were in the form of acoustic characteristics such as acoustic pressure, acoustic velocity, acoustic stream, mixing index, and fluid flow behaviour at various Reynolds numbers. The results revealed that the inclusion of micropillars improved the mixing performance and strength of the acoustic field, resulting in an improvement of the mixing performance compared to the case without micropillars. In addition, the mixing performance is also investigated at different Reynolds numbers, and a higher mixing index is investigated at lower Reynolds numbers. Moreover, it was also investigated that blade-shaped micropillars with 0.150 mm gaps deliver the best results compared to the other cases, and the maximum and minimum values of the mixing index are 0.97 and 0.72, respectively, at Reynolds number 2. The main reason behind this larger mixing index at low Reynolds numbers is due to the inclusion of micropillars that enhance the diffusion rate and contact area, leading to the homogenisation of the heterogeneous fluids in the microchamber. The obtained results can be extremely helpful for the design and modifications of a hybrid microfluidics micromixer. [ABSTRACT FROM AUTHOR]

Published

2024

43. Vibro-acoustic characteristics of a submarine model excited by excitation forces of pump-jet duct.

Author

Zhang, Junyue, Li, Huiyao, and Hua, Hongxing

Subjects

*ACOUSTIC streaming, *COMPUTATIONAL fluid dynamics, *ACOUSTIC radiation, *EXCITATION spectrum, *FINITE element method, *FLUID-structure interaction

Abstract

The vibro-acoustic responses of coupled pump-jet-submarine systems excited by fluid excitations on the wall of the duct are numerically investigated. The unsteady excitations are calculated by computational fluid dynamics and the vibration responses for different excitations on the inner and outer walls are contrastively analyzed through establishing a finite element model of the coupled system. Meanwhile, the effect of fluid–structure interaction and the excitation loading methods for the inner flow of duct are considered. The sound radiation characteristics for different excitation sources are predicted through using a boundary element model. The results show that the excitation force spectra of the inner wall have a remarkable discrete peak at blade passing frequency and its multiple, while the excitation force spectra of the outer wall show a broadband characteristic and discrete components appear at blade passing frequency. The modes of hull both dominate the vibro-acoustic responses of the coupled system for different excitation sources of the duct. The transmitted energy for inner excitation forces is significantly greater than that of outer excitation forces, but the sound radiation efficiency is relatively close. The excitations of the duct can transfer to the thrust bearing through stators as well as the hull and cause a coupled vibration between the duct–stator–hull and the shafting system. Besides, the method for applying distributed forces on the inner wall is more reliable. [ABSTRACT FROM AUTHOR]

Published

2024

44. Simulation study on the flow-induced vibration and noise in marine centrifugal pumps.

Author

Zhao, Cunsheng and Chai, Kai

Subjects

*CENTRIFUGAL pumps, *ACOUSTIC field, *SOUND pressure, *FLUID pressure, *STRUCTURAL dynamics, *NOISE, *ACOUSTIC streaming

Abstract

Due to the three-dimensional non-axisymmetric shape of the volute, its interaction with the impeller increases the internal flow field complexity and instability of the marine centrifugal pump, representing the main reason for pump body vibration and hydraulic noise. First, the basic principle of fluid machinery noise calculation was explained based on the Lighthill acoustic analogy method and Curle's theory. Then, the fluid pressure pulsation and flow characteristics of centrifugal pumps were analyzed using the Fluent software, after which the Actran software was used to examine the flow-induced vibration noise properties. The results showed that the clearance size significantly impacted the pump head, while the peak value of the flow-induced vibration response was mainly twice the blade frequency. Although a larger ring clearance increased the structural vibration, it had little impact on the sound pressure level changes in the external sound field. The results provided a new method for the structural optimization and low-noise design of marine centrifugal pumps. [ABSTRACT FROM AUTHOR]

Published

2024

45. Mesoscale Eddy Effects on Vertical Correlation of Sound Field and Array Gain Performance.

Author

Wu, Yushen, Qin, Jixing, Wu, Shuanglin, Li, Zhenglin, Wang, Mengyuan, Gu, Yiming, and Wang, Yang

Subjects

*ACOUSTIC field, *MESOSCALE eddies, *SPEED of sound, *DEPTH sounding, *EDDIES, *TRANSMISSION of sound, *ACOUSTIC wave propagation, *ACOUSTIC streaming

Abstract

To solve the problem of array detection performance in environments with mesoscale eddies, this study utilizes the Gaussian eddy model to describe the sound speed structure disturbed by eddies. Through numerical simulations, the corresponding sound field is obtained, and the transmission loss influenced by the eddy is analyzed. Furthermore, to investigate the relation between the array gain and spatial correlation in the eddy environments, the differences in vertical correlation at different positions and their effects on the vertical array gain of conventional beamforming (CBF) are studied. When the source is around the eddy center, the conclusions drawn are as follows: (1) The presence of an eddy changes the turning-point depth and the sound field distribution, significantly affecting the direct sound region and the first convergence zone, while having a minor impact on the first shadow zone. (2) In different eddy-induced environments, the first convergence zone maintains a high vertical correlation, but the vertical correlation of the direct sound region is greatly influenced by the eddy. (3) The array gain of CBF is consistent with the vertical correlation. When the correlation between each element of the sound field is great, the array gain increases with the number of array elements. [ABSTRACT FROM AUTHOR]

Published

2024

46. A Boundary Element Method for Acoustic Problems in Relative Motion Between Source and Fluid.

Author

Sun, Ruihua, Wu, Haijun, Jiang, Weikang, Ji, Liang, and Li, Danwang

Subjects

*RELATIVE motion, *BOUNDARY element methods, *FAST multipole method, *COORDINATE transformations, *LORENTZ spaces, *EQUATIONS of motion, *WAVE equation, *ACOUSTIC streaming

Abstract

To calculate the acoustic problems of relative uniform motion between the acoustic source and the fluid, we propose a boundary element method (BEM) strategy that can calculate various forms of relative uniform motion in subsonic conditions in a unified framework and is simple to implement. The acceleration algorithm for the BEM, like the fast multipole method (FMM), in the relative motionless state between the source and the fluid can be directly used without major modifications to the program. We propose a two-step transformation method to unify the wave equations of different relative motion forms into the classical form. In the first step, we transform the wave equations for various forms of relative motion into the equation where the convective terms are present only in the source part. Then, in the second step, we propose an acoustic-analogy Lorentz (a-a Lorentz) transformation to apply Lorentz covariance further to eliminate the convection term and establish the wave equation with classical form in a-a Lorentz space. We implement the boundary integration in the transformed a-a Lorentz space and derive a transformation method to transform discretized geometry and boundary conditions in the original space to the a-a Lorentz space. The problem that the boundary conditions are difficult to apply when solving the boundary integral equation (BIE) after the time-space coordinate transformation is solved. Numerical validations for the proposed method are performed by comparing with analytical results over a wide range of relative velocities. The results show that the proposed method can efficiently compute such problems with high accuracy and concise formulation. [ABSTRACT FROM AUTHOR]

Published

2024

47. Distinguishing climate change impacts from development impacts on summer low flows in Puget Sound streams.

Author

Georgiadis, Nicholas, Bogue, Kevin, and DeGasperi, Curtis

Subjects

*ACOUSTIC streaming, *CLIMATE change, *GLOBAL warming, *LAND cover, *RURAL development, *WELLS

Abstract

In many Puget Sound streams, summer low flows have declined in recent decades, and are projected to decline further. Concerns that humans may be responsible have focused on two main causes: anthropogenic climate warming and aspects of development, including urbanization and the abstraction of groundwater. Difficulty in distinguishing their relative impacts has hindered the conception and design of strategies intended to restore and enhance future low flows. We analyzed trends in low flows over recent decades, separating the effects of these factors in two steps. First, low flow variation was assessed in 23 basins that are minimally disturbed by development. Low flows varied over time, and with elevation, in complex ways, consistent with the loss of snowpack at elevations >~800 m. Second, low flow trends in developed lowland basins were compared with trends in a minimally developed lowland reference basin. Flows in developed basins deviated from a purely climate‐driven pattern in unique ways, reflecting unique histories of development. In 21 lowland basins, there was no consistent decline in low flows with increasing impervious land cover, at least between 2001 and 2019. Effects on low flows of private wells alone could be assessed in only one basin, but no impact was evident. An assessment of projected relative impacts on low flows of urbanization, rural development, and anthropogenic warming suggested that the latter will be the greatest. [ABSTRACT FROM AUTHOR]

Published

2024

48. Numerical prediction of mean flow and acoustic field of a supersonic impinging jet.

Author

Kourbatski, Konstantine A.

Subjects

*ACOUSTIC field, *ACOUSTIC radiation, *SOUND pressure, *ACOUSTIC streaming, *AUDIO frequency, *TURBULENT flow, *JET impingement

Abstract

The three-dimensional turbulent mean flow and acoustic field of a supersonic jet impinging on a solid plate is studied computationally using the general purpose CFD code Ansys Fluent. A pressure-based coupled solver formulation with the second order weighted central-upwind spatial discretization is applied to compute transient solutions. Cold and hot jet thermal conditions are considered. Mean flow characteristics are investigated by a steady-state modeling approach. Acoustic radiation of impingement tones is simulated using a transient time-domain formulation. The effects of turbulence in steady-state are modeled by the SST k-ω turbulence model. The Wall-Modeled Large-Eddy Simulation (WMLES) model is applied to compute transient solutions. The near-wall mesh on the impingement plate is fine enough to resolve the viscosity-affected near-wall region all the way to the laminar sublayer. Nozzle-to-plate distance is parameterized in the model for automatic re-generation of the mesh and results. Steady-state predictions of hover lift loss and mean jet velocity distributions are compared with experimental data, and favorable agreement is reported. The transient solution reproduces the mechanism of impingement tone generation by the interaction of large scale vortical structures with the impingement plate. The acoustic near-field is directly resolved by Computational Aeroacoustics (CAA) to accurately propagate impingement tone waves to near-field microphone locations. Calculated impingement tone frequencies and sound pressure levels agree with experimental values. [ABSTRACT FROM AUTHOR]

Published

2024

49. Unsteady flow behaviors and flow-induced noise characteristics in a closed branch T-junction.

Author

Zhang, Haoyuan, Wang, Peng, Liu, Hong, Wang, Benlong, and Liu, Yingzheng

Subjects

*KELVIN-Helmholtz instability, *ACOUSTIC radiators, *TURBULENCE, *PROPER orthogonal decomposition, *TURBULENT flow, *ACOUSTIC streaming, *UNSTEADY flow, *SOUND pressure, *LARGE eddy simulation models

Abstract

In the present study, dynamic delayed detached eddy simulation is utilized to explore turbulent flow in T-junctions at a Reynolds number of ReD = 2.0 × 104. Three systems with varying corner cavity depth-to-diameter ratios (Ld/D = 1, 2, and 4) are examined to elucidate the interplay between unsteady flow and flow-induced noise. The analysis employs Lighthill's acoustic analogy to scrutinize surface dipole acoustic sources and their noise propagation characteristics. Coherent flow structures, characterized as wavepackets, are identified through spectral proper orthogonal decomposition, demonstrating consistent dominance in modes and dipole distributions across the systems. In the system with Ld/D = 1, wavepackets originating from the downstream region of the junction exhibit a pronounced flapping behavior attributed to the Kelvin–Helmholtz instability. Most dissipate with the mainstream flow, whereas a portion interacts with the wall, forming dipole acoustic sources. For systems with Ld/D = 2 and 4, the dominant mode transitions to the junction adjacent to the corner cavity, expanding continuously after separation until obliquely colliding with the wall, resulting in expanded dipole distributions. Mechanisms underlying flow-induced noise generation are unveiled by extracting transient vorticity fields within oscillation cycles. For shallow corner cavity depths (Ld/D = 1), periodic oscillatory vorticity shedding from the junction's sidewall significantly contributes to far-field sound pressure. As the cavity is deep enough to support one or more full recirculations of the fluid (Ld/D = 2 and 4), periodic vorticity shedding from the trailing edge directly impacts the wall above the junction, simultaneously suppressing flapping behavior at the leading edge and weakening overall dipole acoustic source intensity. [ABSTRACT FROM AUTHOR]

Published

2024

50. Self-supervised transformers for turbulent flow time series.

Author

Drikakis, Dimitris, Kokkinakis, Ioannis William, Fung, Daryl, and Spottswood, S. Michael

Subjects

*TURBULENCE, *TRANSFORMER models, *TURBULENT flow, *TIME series analysis, *DEEP learning, *TRANSONIC flow, *ACOUSTIC streaming

Abstract

There has been a rapid advancement in deep learning models for diverse research fields and, more recently, in fluid dynamics. This study presents self-supervised transformers' deep learning for complex turbulent flow signals across various test problems. Self-supervision aims to leverage the ability to extract meaningful representations from sparse flow time-series data to improve the transformer model accuracy and computational efficiency. Two high-speed flow cases are considered: a supersonic compression ramp and shock-boundary layer interaction over a statically deformed surface. Several training scenarios are investigated across the two different supersonic configurations. The training data concern wall pressure fluctuations due to their importance in aerodynamics, aeroelasticity, noise, and acoustic fatigue. The results provide insight into transformers, self-supervision, and deep learning with application to complex time series. The architecture is extendable to other research domains where time series data are essential. [ABSTRACT FROM AUTHOR]

Published

2024