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Książki na temat „Acoustic identification”

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Autor: Grafiati
Data publikacji: 4 czerwca 2021
Data aktualizacji: 2 lutego 2022

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1

Helwani, Karim. Adaptive Identification of Acoustic Multichannel Systems Using Sparse Representations. Cham: Springer International Publishing, 2015. http://dx.doi.org/10.1007/978-3-319-08954-6.

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2

Banks, H. Thomas. Parameter estimation in a structural acoustic system with fully nonlinear coupling conditions. Hampton, Va: Institute for Computer Applications in Science and Engineering, NASA Langley Research Center, 1994.

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3

Farren, Maureen A. Some experiments with underwater acoustic returns from cylinders relative to object identification for AUV operation. Monterey, California: Naval Postgraduate School, 1988.

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4

Healey, Anthony J. Sonar signal acquisition and processing for identification and classification of ship hull fouling. Monterey, Calif: Naval Postgraduate School, 1993.

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5

Hanson, David R. Multiple-channel trigger circuit for noise discrimination in ultrasonic acoustic emission studies. Washington, DC: U.S. Dept. of the Interior, Bureau of Mines, 1995.

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6

Hanson, David R. Multiple-channel trigger circuit for noise discrimination in ultrasonic acoustic emission studies. [Washington, D.C.?]: U.S. Dept. of the Interior, Bureau of Mines, 1995.

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7

Hanson, David R. Multiple-channel trigger circuit for noise discrimination in ultrasonic acoustic emission studies. [Washington, D.C.?]: U.S. Dept. of the Interior, Bureau of Mines, 1995.

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8

Hanson, David R. Multiple-channel trigger circuit for noise discrimination in ultrasonic acoustic emission studies. [Washington, D.C.?]: U.S. Dept. of the Interior, Bureau of Mines, 1995.

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9

Hanson, David R. Multiple-channel trigger circuit for noise discrimination in ultrasonic acoustic emission studies. [Washington, D.C.?]: U.S. Dept. of the Interior, Bureau of Mines, 1995.

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10

Fuller, C. R. Application of pattern recognition techniques to the identification of aerospace acoustic sources: Annual report, year one. [Washington, DC: National Aeronautics and Space Administration, 1988.

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11

Ahgren, Per. On System Identification And Acoustic Echo Cancellation. Coronet Books, 2004.

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12

Helwani, Karim. Adaptive Identification of Acoustic Multichannel Systems Using Sparse Representations. Springer, 2016.

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13

Helwani, Karim. Adaptive Identification of Acoustic Multichannel Systems Using Sparse Representations. Springer, 2014.

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14

C, Smith R., i Institute for Computer Applications in Science and Engineering., red. Parameter estimation in a structural acoustic system with fully nonlinear coupling conditions. Hampton, Va: Institute for Computer Applications in Science and Engineering, NASA Langley Research Center, 1994.

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15

United States. Bureau of Mines, red. Multiple-channel trigger circuit for noise discrimination in ultrasonic acoustic emission studies. [Washington, D.C.?]: U.S. Dept. of the Interior, Bureau of Mines, 1995.

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16

Multiple-channel trigger circuit for noise discrimination in ultrasonic acoustic emission studies. [Washington, D.C.?]: U.S. Dept. of the Interior, Bureau of Mines, 1995.

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17

Nagl, Michael Martin. Identification of the mechanism of oxide scale fracture, and its correlation with strain using acoustic emission. 1992.

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18

Recasens, Daniel. Phonetic Causes of Sound Change. Oxford University Press, 2020. http://dx.doi.org/10.1093/oso/9780198845010.001.0001.

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The present study sheds light on the phonetic causes of sound change and the intermediate stages of the diachronic pathways by studying the palatalization and assibilation of velar stops (referred to commonly as ‘velar softening’, as exemplified by the replacement of Latin /ˈkɛntʊ/ by Tuscan Italian [ˈtʃɛnto] ‘one hundred’), and of labial stops and labiodental fricatives (also known as’ labial softening’, as in the case of the dialectal variant [ˈtʃatɾə] of /ˈpjatɾə/ ‘stone’ in Romanian dialects). To a lesser extent, it also deals with the palatalization and affrication of dentoalveolar stops. The book supports an articulation-based account of those sound-change processes, and holds that, for the most part, the corresponding affricate and fricative outcomes have been issued from intermediate (alveolo)palatal-stop realizations differing in closure fronting degree. Special attention is given to the one-to-many relationship between the input and output consonantal realizations, to the acoustic cues which contribute to the implementation of these sound changes, and to those positional and contextual conditions in which those changes are prone to operate most feasibly. Different sources of evidence are taken into consideration: descriptive data from, for example, Bantu studies and linguistic atlases of Romanian dialects in the case of labial softening; articulatory and acoustic data for velar and (alveolo)palatal stops and front lingual affricates; perceptual results from phoneme identification tests. The universal character of the claims being made derives from the fact that the dialectal material, and to some extent the experimental material as well, belong to a wide range of languages from not only Europe but also all the other continents.
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19

Russ, Jon, red. Bat Calls of Britain and Europe. Pelagic Publishing, 2021. http://dx.doi.org/10.53061/nlhc3923.

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A comprehensive guide to the calls of the 44 species of bat currently known to occur in Europe. Following on from the popular British Bat Calls by Jon Russ, this new book draws on the expertise of more than forty specialist authors to substantially update all sections, further expanding the volume to include sound analysis and species identification of all European bats. Aimed at volunteers and professional alike, topics include the basics of sound, echolocation in bats, an introduction to acoustic communication, equipment used and call analysis. For each species, detailed information is given on distribution, emergence, flight and foraging behaviour, habitat, echolocation calls – including parameters of common measurements – and social calls. Calls are described for both heterodyne and time expansion/full spectrum systems. A simple but complete echolocation guide to all species is provided for beginners, allowing them to analyse call sequences and arrive at the most likely species or group. The book also includes access to a downloadable library of over 450 calls presented as sonograms in the species sections.
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20

Horing, Norman J. Morgenstern. Superfluidity and Superconductivity. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780198791942.003.0013.

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Chapter 13 addresses Bose condensation in superfluids (and superconductors), which involves the field operator ψ‎ having a c-number component (<ψ(x,t)>≠0), challenging number conservation. The nonlinear Gross-Pitaevskii equation is derived for this condensate wave function<ψ>=ψ−ψ˜, facilitating identification of the coherence length and the core region of vortex motion. The noncondensate Green’s function G˜1(1,1′)=−i<(ψ˜(1)ψ˜+(1′))+> and the nonvanishing anomalous correlation function F˜∗(2,1′)=−i<(ψ˜+(2)ψ˜+(1′))+> describe the dynamics and elementary excitations of the non-condensate states and are discussed in conjunction with Landau’s criterion for viscosity. Associated concepts of off-diagonal long-range order and the interpretation of <ψ> as a superfluid order parameter are also introduced. Anderson’s Bose-condensed state, as a phase-coherent wave packet superposition of number states, resolves issues of number conservation. Superconductivity involves bound Cooper pairs of electrons capable of Bose condensation and superfluid behavior. Correspondingly, the two-particle Green’s function has a term involving a product of anomalous bound-Cooper-pair condensate wave functions of the type F(1,2)=−i<(ψ(1)ψ(2))+>≠0, such that G2(1,2;1′,2′)=F(1,2)F+(1′,2′)+G˜2(1,2;1′,2′). Here, G˜2 describes the dynamics/excitations of the non-superfluid-condensate states, while nonvanishing F,F+ represent a phase-coherent wave packet superposition of Cooper-pair number states and off-diagonal long range order. Employing this form of G2 in the G1-equation couples the condensed state with the non-condensate excitations. Taken jointly with the dynamical equation for F(1,2), this leads to the Gorkov equations, encompassing the Bardeen–Cooper–Schrieffer (BCS) energy gap, critical temperature, and Bogoliubov-de Gennes eigenfunction Bogoliubons. Superconductor thermodynamics and critical magnetic field are discussed. For a weak magnetic field, the Gorkov-equations lead to Ginzburg–Landau theory and a nonlinear Schrödinger-like equation for the pair wave function and the associated supercurrent, along with identification of the Cooper pair density. Furthermore, Chapter 13 addresses the apparent lack of gauge invariance of London theory with an elegant variational analysis involving re-gauging the potentials, yielding a manifestly gauge invariant generalization of the London equation. Consistency with the equation of continuity implies the existence of Anderson’s acoustic normal mode, which is supplanted by the plasmon for Coulomb interaction. Type II superconductors and the penetration (and interaction) of quantized magnetic flux lines are also discussed. Finally, Chapter 13 addresses Josephson tunneling between superconductors.
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