Ultrasonic Guided Waves
dc.contributor.author | Lissenden, Clifford J. | * |
dc.date.accessioned | 2021-02-12T06:50:19Z | |
dc.date.available | 2021-02-12T06:50:19Z | |
dc.date.issued | 2020 | * |
dc.date.submitted | 2020-04-07 23:07:09 | * |
dc.identifier | 44824 | * |
dc.identifier.uri | https://directory.doabooks.org/handle/20.500.12854/61481 | |
dc.description.abstract | The propagation of ultrasonic guided waves in solids is an important area of scientific inquiry, primarily due to their practical applications for nondestructive characterization of materials, such as nondestructive inspection, quality assurance testing, structural health monitoring, and providing a material state awareness. This Special Issue of Applied Sciences covers all aspects of ultrasonic guided waves (e.g., phased array transducers, meta-materials to control wave propagation characteristics, scattering, attenuation, and signal processing techniques) from the perspective of modeling, simulation, laboratory experiments, or field testing. In order to fully utilize ultrasonic guided waves for these applications, it is necessary to have a firm grasp of their requisite characteristics, which include that they are multimodal, dispersive, and are comprised of unique displacement profiles through the thickness of the waveguide. | * |
dc.language | English | * |
dc.subject | TA1-2040 | * |
dc.subject | T1-995 | * |
dc.subject.classification | thema EDItEUR::T Technology, Engineering, Agriculture, Industrial processes::TB Technology: general issues::TBX History of engineering and technology | en_US |
dc.subject.other | n/a | * |
dc.subject.other | fault diagnosis | * |
dc.subject.other | stoneley wave | * |
dc.subject.other | acoustic leakage | * |
dc.subject.other | structural health monitoring | * |
dc.subject.other | modified BEM | * |
dc.subject.other | composite | * |
dc.subject.other | dispersive medium | * |
dc.subject.other | multi-wire cable | * |
dc.subject.other | semi-analytical finite element | * |
dc.subject.other | axial transmission | * |
dc.subject.other | circumferential scanning | * |
dc.subject.other | guided wave | * |
dc.subject.other | wavenumber domain filtering | * |
dc.subject.other | square steel bar | * |
dc.subject.other | exploding reflector model | * |
dc.subject.other | ultrasonic guided waves (UGWs) | * |
dc.subject.other | sliding window | * |
dc.subject.other | fiber optics | * |
dc.subject.other | numerical modelling | * |
dc.subject.other | pressure vessels | * |
dc.subject.other | surface waves | * |
dc.subject.other | resonator | * |
dc.subject.other | fiber Bragg grating | * |
dc.subject.other | dispersion curves | * |
dc.subject.other | power spectrum | * |
dc.subject.other | pipe inspection | * |
dc.subject.other | non-destructive testing | * |
dc.subject.other | hybrid and non-contact system | * |
dc.subject.other | SNR | * |
dc.subject.other | group velocity | * |
dc.subject.other | rayleigh wave | * |
dc.subject.other | signal strength enhancement | * |
dc.subject.other | ultrasonic guided-waves (UGWs) | * |
dc.subject.other | low-frequency | * |
dc.subject.other | adhesive joint | * |
dc.subject.other | ultrasonic guided waves | * |
dc.subject.other | signal processing | * |
dc.subject.other | lamb waves | * |
dc.subject.other | SH0 mode | * |
dc.subject.other | non-detection zone | * |
dc.subject.other | leakage location | * |
dc.subject.other | damage identification | * |
dc.subject.other | air-coupled transducer | * |
dc.subject.other | nondestructive testing | * |
dc.subject.other | defect location | * |
dc.subject.other | defect detection | * |
dc.subject.other | guided waves | * |
dc.subject.other | magnetostrictive patch transducer | * |
dc.subject.other | Rayleigh wave | * |
dc.subject.other | array analysis | * |
dc.subject.other | pipeline inspection | * |
dc.subject.other | synthetic aperture focusing | * |
dc.subject.other | single lap joint | * |
dc.subject.other | adaptive filtering | * |
dc.subject.other | elastodynamics | * |
dc.subject.other | scanning laser vibrometry | * |
dc.subject.other | split-spectrum processing | * |
dc.subject.other | leaky normalized mean square | * |
dc.subject.other | rail | * |
dc.subject.other | SNR enhancement | * |
dc.subject.other | slowness curves | * |
dc.subject.other | wave structure | * |
dc.subject.other | Lamb wave | * |
dc.subject.other | scattering | * |
dc.subject.other | ultrasonic testing | * |
dc.subject.other | acoustic emission | * |
dc.subject.other | soft magnetic patch | * |
dc.subject.other | energy transfer | * |
dc.subject.other | metamaterial | * |
dc.subject.other | dynamic magnetic field optimization | * |
dc.subject.other | spatial domain | * |
dc.subject.other | ultrasonic guided wave | * |
dc.subject.other | contact acoustic nonlinearity | * |
dc.subject.other | time-frequency domain reflectometry | * |
dc.subject.other | shear mode | * |
dc.subject.other | lamb wave | * |
dc.subject.other | partial wave method | * |
dc.subject.other | phase velocity | * |
dc.subject.other | Lamb waves | * |
dc.subject.other | mode sorting | * |
dc.subject.other | torsional wave | * |
dc.subject.other | single mode extraction algorithm | * |
dc.subject.other | electromagnetic wave | * |
dc.subject.other | reconstruction | * |
dc.subject.other | surface flaw | * |
dc.subject.other | local wavenumber | * |
dc.title | Ultrasonic Guided Waves | * |
dc.type | book | |
oapen.identifier.doi | 10.3390/books978-3-03928-299-9 | * |
oapen.relation.isPublishedBy | 46cabcaa-dd94-4bfe-87b4-55023c1b36d0 | * |
oapen.relation.isbn | 9783039282982 | * |
oapen.relation.isbn | 9783039282999 | * |
oapen.pages | 376 | * |
oapen.edition | 1st | * |
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