Introduction to Acoustics

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454 Part D Hearing and Signal Processing Part D 12 12.32 M.B. Sachs, I.C. Bruce, E.D. Young: The biological basis of hearing-aid design, Ann. BME 30, 157–168 (2002) 12.33 G. von Bekesy: Experiments in Hearing (McGraw- Hill, New York 1960) 12.34 L. Robles, M.A. Ruggero: Mechanics of the mammalian cochlea, Physiol. Rev. 81, 1305–1352 (2001) 12.35 D.H. Eldredge: Electrical equivalents of the Bekesy traveling wave in the mammalian cochlea. In: Evoked Electrical Activity in the Auditory Nervous System, ed. by R.F. Naunton, C. Fernandez (Academic, New York 1978) 12.36 M.A. Ruggero, N.C. Rich, A. Recio, S.S. Narayan: Basilar-membrane responses to tones at the base of the chinchilla cochlea, J. Acoust. Soc. Am. 101, 2151–2163 (1997) 12.37 N.P. Cooper, W.S. Rhode: Mechanical responses to two-tone distortion products in the apical and basal turns of the mammalian cochlea, J. Neurophysiol. 78, 261–270 (1997) 12.38 W.S. Rhode: Observations of the vibration of the basilar membrane in squirrel monkeys using the Mossbauer technique, J. Acoust. Soc. Am. 49, 1218– 1231 (1971) 12.39 D. Brass, D.T. Kemp: Analyses of Mossbauer mechanical measurements indicate that the cochlea is mechanically active, J. Acoust. Soc. Am. 93,1502– 1515 (1993) 12.40 P. Dallos: The active cochlea, J. Neurosci. 12, 4575– 4585 (1992) 12.41 H. Davis: An active process in cochlear mechanics, Hear Res. 9, 79–90 (1983) 12.42 R.J. Diependaal, E. de Boer, M.A. Viergever: Cochlear power flux as an indicator of mechanical activity, J. Acoust. Soc. Am. 82, 917–926(1987) 12.43 G.A. Manley: Evidence for an active process and a cochlear amplifier in nonmammals, J. Neurophysiol. 86, 541–549 (2001) 12.44 E. Zwicker: A model describing nonlinearities in hearing by active processes with saturation at 40 dB, Biol. Cybern. 35, 243–250 (1979) 12.45 D.T. Kemp: Stimulated acoustic emissions from within the human auditory system, J. Acoust. Soc. Am. 64, 1386–1391 (1978) 12.46 C.A. Shera: Mechanisms of mammalian otoacoustic emission and their implications for the clinical utility of otoacoustic emissions, Ear Hearing 25, 86–97 (2004) 12.47 C.L. Talmadge, A. Tubis, G.R. Long, C. Tong: Modeling the combined effects of basilar membrane nonlinearity and roughness on stimulus frequency otoacoustic emission fine structure, J. Acoust. Soc. Am. 108, 2911–2932 (2000) 12.48 G. Zweig, C.A. Shera: The origin of periodicity in the spectrum of evoked otoacoustic emissions, J. Acoust. Soc. Am. 98, 2018–2047 (1995) 12.49 R. Patuzzi: Cochlear micromechanics and macromechanics. In: The Cochlea, ed. by P. Dallos, A.N. Popper, R.R. Fay (Springer, Berlin, New York 1996) 12.50 E. de Boer, A.L. Nuttall, N. Hu, Y. Zou, J. Zheng: The Allen-Fahey experiment extended, J. Acoust. Soc. Am. 117, 1260–1266 (2005) 12.51 M.C. Liberman, L.W. Dodds: Single-neuron labeling and chronic cochlear pathology. III. Stereocilia damage and alterations of threshold tuning curves, Hearing Res. 16, 55–74 (1984) 12.52 E. Murugasu, I.J. Russell: The effect of efferent stimulation on basilar membrane displacement in the basal turn of the guinea pig cochlea, J. Neurosci. 16, 325–332 (1996) 12.53 M.C. Brown, A.L. Nuttall: Efferent control of cochlear inner hair cell responses in the guineapig, J. Physiol. 354, 625–646 (1984) 12.54 M.L. Wiederhold, N.Y.S. Kiang: Effects of electric stimulation of the crossed olivocochlear bundle on single auditory-nerve fibers in the cat, J. Acoust. Soc. Am. 48, 950–965 (1970) 12.55 M.C. Liberman, S. Puria, J.J. Guinan: The ipsilaterally evoked olivocochlear reflex causes rapid adaptation of the 2f1–f2 distortion product otoacoustic emission, J. Acoust. Soc. Am. 99, 3572–3584 (1996) 12.56 D.C. Mountain: Changes in endolymphatic potential and crossed olivocochlear bundle stimulation alter cochlear mechanics, Science 210, 71–72 (1980) 12.57 M.A. Ruggero, N.C. Rich, A. Recio: The effect of intense acoustic stimulation on basilar-membrane vibrations, Aud. Neurosci. 2, 329–345 (1996) 12.58 A.J. Oxenham, S.P. Bacon: Cochlear compression: Perceptual measures and implications for normal and impaired hearing, Ear Hearing 24, 352–366 (2003) 12.59 D.A. Nelson, A.C. Schroder, M. Wojtczak: A new procedure for measuring peripheral compression in normal-hearing and hearing-impaired listeners, J. Acoust. Soc. Am. 110, 2045–2064 (2001) 12.60 A.J. Oxenham, C.J. Plack: A behavioral measure of basilar-membrane nonlinearity in listeners with normal and impaired hearing, J. Acoust. Soc. Am. 101, 3666–3675 (1997) 12.61 E. de Boer: Mechanics of the cochlea: Modeling efforts. In: The Cochlea, ed. by P. Dallos, A.N. Popper, R.R. Fay (Springer, Berlin, New York 1996) 12.62 A.E. Hubbard, D.C. Mountain: Analysis and synthesis of cochlear mechanical function using models. In: Auditory Computation, ed. by H.L. Hawkins, T.A. McMullen, A.N. Popper, R.R. Fay (Springer, Berlin, New York 1996) 12.63 R.C. Naidu, D.C. Mountain: Measurements of the stiffness map challenge a basic tenet of cochlear theories, Hearing Res. 124, 124–131 (1998) 12.64 M.P. Sherer, A.W. Gummer: Impedance analysis of the organ of corti with magnetically actuated probes, Biophys. J. 87, 1378–1391 (2004)
12.65 M.B. Sachs: Speech encoding in the auditory nerve. In: Hearing Science Recent Advances, ed. by C.I. Berlin (College Hill, San Diego 1984) 12.66 J.J. Eggermont: Between sound and perception: reviewing the search for a neural code, Hear Res. 157, 1–42 (2001) 12.67 B.C.J. Moore: Coding of sounds in the auditory system and its relevance to signal processing and coding in cochlear implants, Otol. Neurotol. 24, 243–254 (2003) 12.68 I.C. Bruce, M.B. Sachs, E.D. Young: An auditoryperiphery model of the effects of acoustic trauma on auditory nerve responses, J. Acoust. Soc. Am. 113, 369–388 (2003) 12.69 S.D. Holmes, C. Sumner, L.P. O’Mard, R. Meddis: The temporal representation of speech in a nonlinear model of the guinea pig cochlea, J. Acoust. Soc. Am. 116, 3534–3545 (2004) 12.70 X. Zhang, M.G. Heinz, I.C. Bruce, L.H. Carney: A phenomenological model for the responses of auditory-nerve fibers: I. Nonlinear tuning with compression and suppression, J. Acoust. Soc. Am. 109, 648–670 (2001) 12.71 H.S. Colburn, L.H. Carney, M.G. Heinz: Quantifying the information in auditory-nerve responses for level discrimination, J. Assoc. Res. Otolaryngol. 4, 294–311 (2003) 12.72 B.C.J. Moore: An Introduction to the Psychology of Hearing (Elsevier, London 2004) 12.73 P.A. Cariani, B. Delgutte: Neural correlates of the pitch of complex tones. II. Pitch shift, pitch ambiguity, phase invariance, pitch circularity, rate pitch, and the dominance region for pitch, J. Neurophysiol. 76, 1717–1734 (1996) 12.74 R.L. Miller, J.R. Schilling, K.R. Franck, E.D. Young: Effects of acoustic trauma on the representation of the vowel /ε/ in cat auditory nerve fibers, J. Acoust. Soc. Am. 101, 3602–3616 (1997) 12.75 D.H. Johnson: The relationship of post-stimulus time and interval histograms to the timing characteristics of spike trains, Biophys. J. 22(3), 413–430 (1978) 12.76 M.C. Liberman: Auditory-nerve response from cats raised in a low-noise chamber, J. Acoust. Soc. Am. 63, 442–455 (1978) 12.77 G.K. Yates, I.M. Winter, D. Robertson: Basilar membrane nonlinearity determines auditory nerve rate-intensity functions and cochlear dynamic range, Hearing Res. 45, 203–220 (1990) 12.78 B.C.J. Moore: Perceptual Consequences of Cochlear Damage (Oxford Univ. Press, Oxford 1995) 12.79 M.G. Heinz, J.B. Issa, E.D. Young: Auditory-nerve rate responses are inconsistent with common hypotheses for the neural correlates of loudness recruitment, J. Assoc. Res. Otolaryngol. 6, 91–105 (2005) 12.80 J.O. Pickles: Auditory-nerve correlates of loudness summation with stimulus bandwidth, in normal Physiological Acoustics References 455 and pathological cochleae, Hearing Res. 12, 239– 250 (1983) 12.81 E.M. Relkin, J.R. Doucet: Is loudness simply proportional to the auditory nerve spike count?, J. Acoust. Soc. Am. 101, 2735–2740 (1997) 12.82 S. Rosen: Temporal information in speech: acoustic, auditory and linguistic aspects, Philos. Trans. R. Soc. London B. 336, 367–373 (1992) 12.83 A.R. Palmer, I.J. Russell: Phase-locking in the cochlear nerve of the guinea-pig and its relation to the receptor potential of inner hair-cells, Hear Res. 24, 1–15 (1986) 12.84 T.C.T. Yin: Neural mechanisms of encoding binaural localization cues in the auditory brainstem. In: Integrative Functions in the Mammalian Auditory Pathway, ed. by D. Oertel, A.N. Popper, R.R. Fay (Springer, Berlin, New York 2002) 12.85 S.A. Shamma: Speech processing in the auditory system. II: Lateral inhibition and the central processing of speech evoked activity in the auditory nerve, J. Acoust. Soc. Am. 78, 1622–1632 (1985) 12.86 P. Dallos, B. Fakler: Prestin, a new type of motor protein, Nature Rev. Molec. Bio. 3, 104–111 (2002) 12.87 R.A. Eatock, K.M. Hurley: Functional development of hair cells, Curr. Top. Dev. Bio. 57, 389–448 (2003) 12.88 R. Fettiplace, C.M. Hackney: The sensory and motor roles of auditory hair cells, Nature Rev. Neurosci. 7, 19–29 (2006) 12.89 M. LeMasurier, P.G. Gillespie: Hair-cell mechanotransduction and cochlear amplification, Neuron. 48, 403–415 (2005) 12.90 G.I. Frolenkov, I.A. Belyantseva, T.B. Friedmann, A.J. Griffith: Genetic insights into the morphogenesis of inner ear hair cells, Nature Rev. Genet. 5, 489–498 (2004) 12.91 J.O. Pickles, S.D. Comis, M.P. Osborne: Cross-links between stereocilia in the guinea pig organ of Corti, and their possible relation to sensory transduction, Hear Res. 15, 103–112 (1984) 12.92 A. Flock: Transducing mechanisms in the lateral line canal organ receptors, Cold Spring Harb. Symp. Quant. Biol. 30, 133–145 (1965) 12.93 S.L. Shotwell, R. Jacobs, A.J. Hudspeth: Directional sensitivity of individual vertebrate hair cells to controlled deflection of their hair bundles, Ann. NY Acad. Sci. 374, 1–10 (1981) 12.94 J.A. Assad, G.M.G. Shepherd, D.P. Corey: Tip-link integrity and mechanical transduction in vertebrate hair cells, Neuron 7, 985–994 (1991) 12.95 M.A. Ruggero, N.C. Rich: Timing of spike initiation in cochlear afferents: dependence on site of innervation, J. Neurophysiol. 58, 379–403 (1987) 12.96 E. Glowatzki, P.A. Fuchs: Transmitter release at the hair cell ribbon synapse, Nature Neurosci. 5, 147– 154 (2002) 12.97 L.O. Trussell: Transmission at the hair cell synapse, Nature Neurosci. 5, 85–86 (2002) Part D 12
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Springer Handbook of Acoustics
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Springer Handbook of Acoustics Thom
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Foreword The present handbook cover
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List of Authors Iskander Akhatov No
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Philippe Roux Université Joseph Fo
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XIV Contents 3.7 Attenuation of Sou
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XVI Contents 10 Concert Hall Acoust
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XVIII Contents 17.8 Physical Modeli
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XX Contents 24.5 Free-Field Microph
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XXII List of Abbreviations K KDP po
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Introduction 1. Introduction to Aco
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of noise have been the subject of c
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in order to understand how objectiv
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A Brief 2. A Brief History of Acous
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of 350 m/s for the speed of sound [
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number and relative strength of its
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To his contemporaries, Koenig was p
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Probably the most important use of
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piezoelectric ceramic compositions
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surveys together [2.46]. Masking of
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ther of computer music, since he de
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Basic 3. Linear Basic Linear Acoust
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M average molecular weight n unit v
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a) b) S v.n ∆t ∆S V |v| ∆t n
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temperature, q =−κ∇T , (3.16)
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The equivalent density M/V is conse
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Basic Linear Acoustics 3.3 Equation
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Because any vector field may be dec
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The latter and (3.84), in a manner
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assumed to have no ambient motion,
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Because the friction associated wit
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3.5 Waves of Constant Frequency One
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3.5.4 Time Averages of Products Whe
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as well as symmetry considerations,
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The auxiliary internal variables th
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Then the transient at a distant pos
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ω ′ = 0, and this is consistent
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1.0 10 -1 10 -2 10 -3 10 -4 10 -5 A
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This yields the interpretation that
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direction of propagation when a pla
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so the time-averaged incident energ
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Although the simple result of (3.31
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ut, also in keeping with the linear
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equation, the two differential equa
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Rodrigues relation, one has �1
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for the derivative.) In the asympto
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The differential scattering cross s
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elow) is F(t) = (2c) 1/2 �t −
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0.5 0 -0.5 -1.0 -1.5 0 Y0(η) (π/2
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is the Wronskian for the Bessel and
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The function qS is termed the sourc
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The appropriate identification for
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where jℓ is the spherical Bessel
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this subtlety taken into account, o
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U(x) Basic Linear Acoustics 3.15 Wa
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is ordinarily valid. With these ass
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along rays. These can be regarded a
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A(x0) x0 A(x) Fig. 3.53 Sketch of a
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possible, and one where neither the
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which is independent of the z-coord
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[3.108], and Carslaw [3.109]. In th
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where C(X)andS(X) are the Fresnel i
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Fig. 3.60 Characteristic diffractio
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of elastic solids, Trans. Camb. Phi
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3.101 J.B. Keller: Geometrical acou
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114 Part A Propagation of Sound Par
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Underwater 5. Underwater Acoustics
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5.1 Ocean Acoustic Environment The
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Long-Range Propagation Paths Figure
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tal direction, there is no loss ass
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equivalent circuit, as shown in Fig
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Attenuation á (dB/km) 1000 100 10
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5.2.5 Ambient Noise There are essen
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ubble natural acoustic resonance ω
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a bubbly medium (and for the simple
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As discussed, because detection inv
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(1/A)∇ 2 A ≪ K 2 )sothat(5.34)
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water, where the deep sound channel
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egion in the form p(r, z) = ψ(r, z
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5.4.6 Propagation and Transmission
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tegration interval. The source puls
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5.6 SONAR Array Processing Signal p
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former output is: �∞ b(θ,t) =
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Fig. 5.37 Angle-versus-time represe
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5.7 Active SONAR Processing Depth M
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a factor when there is a reverberan
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depth measurements that correspond
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along the cross-shelf track taken b
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time as a result of multiple paths,
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technique is very sensitive, and ex
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Fig. 5.57a,b Typical echogram obtai
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Frequency (Hz) 150 100 50 0 0 a) b)
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out. These data allow for study of
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5.59 G. Raleigh, J.M. Cioffi: Spati
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Physical 6. Physical Acou Acoustics
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where I is the intensity of the sou
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Wave velocity The wall exerts a dow
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destructively interfered with one a
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or: � � p2 � rms SPL = 10 log
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6.1.4 Wave Propagation in Solids Si
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where c is again the wave speed and
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measured. Some resonances are cause
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as 50 µmto5µm through one oscilla
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the number of false positives and m
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with the small mass), and frequency
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Laser Lens 1 Circular aperture Fig.
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Ground ring Insulator Sample Resist
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Energy ratio 1.0 0.8 0.6 0.4 Calcul
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terms. In this equation γ is the r
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directly. The nonlinearity paramete
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Thermoacoust 7. Thermoacoustics The
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Table 7.1 The acoustic-electric ana
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walls of the pores. (Positive G ind
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a) b) c) C reso d) δtherm e) p 0 U
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a) b) UA,l c) d) E 0 Q A Q A TA TA
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tor. This eliminates the need to le
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to this consumption of acoustic pow
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The traditional Stirling refrigerat
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Washington 1986) pp. 550-554, Softw
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258 Part B Physical and Nonlinear A
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Acoustics 9. Acoustics in Halls for
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parameters, so we can assist in bui
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weeks or even years is less reliabl
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9.3.1 Reverberation Time Reverberan
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selected). A distance different fro
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ing sound, as will naturally be exp
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of the sound fields. Consequently,
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e derived from interrupted noise de
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Acoustics in Halls for Speech and M
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espectively, can be calculated from
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ated by the architects. However, on
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of C and G. However, as all the ind
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F b d F n I S Fb Fn S d F n/F b d/d
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HS S èn ã d0 P0 rn Position of ey
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Time T (s) 2.5 2 1.5 1 5 10 15 Acou
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floor can be tilted to reduce volum
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ÄLcurv (dB) 10 8 6 4 2 0 -2 -4 -6
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Seating capacity 2662 1 915 + 324 2
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4 3 2 1 Acoustics in Halls for Spee
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cially in auditoria with T values l
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esonance (AR)andmultichannel reverb
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Concert 10. Concert Hall Acoustics
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Concert Hall Acoustics Based on Sub
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0 0 Concert Hall Acoustics Based on
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mately by Concert Hall Acoustics Ba
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10.1.5 Specialization of Cerebral H
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The other (n − 1) bits indicated
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As for the conflicting requirements
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have mainly been concerned with tem
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a) c) S S -4.3 -2.8 -2.0 -3.5 -3dB
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a model of the auditory-brain syste
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Building 11. Building Acou Acoustic
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Pressure Maximum Minimum 0 D Distan
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Table 11.1 Absorption coefficients
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Absorption coefficient α 1 0 Frequ
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is of key importance in rooms where
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Table 11.4 Transmission loss and ST
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TL of wall - (TL of door, window or
Page 412 and 413: Table 11.7 Generalized noise reduct
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Page 418 and 419: 11.5 Noise Control Methods for Buil
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Page 430 and 431: 11.6 Acoustical Privacy in Building
Page 432 and 433: Table 11.9 AI,SIIandPIforopenplanof
Page 434 and 435: Electronic sound masking in plenum
Page 436 and 437: E 1179 Standard Specification for S
Page 438 and 439: 430 Part D Hearing and Signal Proce
Page 466 and 467: Psychoacoust 13. Psychoacoustics Ps
Page 468 and 469: Absolute threshold (dB SPL) 100 90
Page 470 and 471: the signal. By using this off-cente
Page 472 and 473: is as a crude indicator of the exci
Page 474 and 475: Relative response (dB) 100 90 80 70
Page 476 and 477: In a variation of this procedure, t
Page 478 and 479: Level of matching noise (dB) 100 90
Page 480 and 481: 13.4 Temporal Processing in the Aud
Page 482 and 483: Most models include an initial stag
Page 484 and 485: The components were either uniforml
Page 486 and 487: (Frequency DL)/ERBN 0.2 0.1 0.05 0.
Page 488 and 489: elaborate place models have been pr
Page 490 and 491: 13.6 Timbre Perception 13.6.1 Time-
Page 492 and 493: the duplex theory of sound localiza
Page 494 and 495: harmonic (by shifting the frequency
Page 496 and 497: sive. While some studies have been
Page 498 and 499: sentences (see Fig. 13.20). They va
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Page 502 and 503: References 13.1 ISO 389-7: Acoustic
Page 504 and 505: 13.74 D. Ronken: Monaural detection
Page 506 and 507: asymmetric function, J. Acoust. Soc
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506 Part D Hearing and Signal Proce
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534 Part E Music, Speech, Electroac
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The 16. The Human Human Voice in Sp
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uation, the effect of gravity is in
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piratory muscles (the internal inte
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Mean Ps (cm H2O) 50 40 30 20 10 0 D
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Glottal flow Closed Opening Open Cl
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Transglottal airflow (l/s) 0.4 0.2
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Mean spectrum level (dB) -30 -40 -5
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20 10 0 -10 -20 -30 -40 -50 0 i y u
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Mean level (dB) 0 -10 -20 -30 -40 1
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This topic was addressed by Ladefog
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Fig. 16.29 Acoustic consequences of
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Bass i e u Alto Tenor o ε œ æ Th
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100 80 60 40 20 0 -20 100 80 60 40
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tours for [� ]and[Ù ] sampled at
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Rapp [16.100] asked three native sp
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Utterance command T0 T3 Accent comm
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The # symbol indicates the possibil
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Second formant frequency (Hz) 2500
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tional rather than absolute (à la
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16.7 P. Ladefoged, M.H. Draper, D.
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esonance imaging: Vowels, J. Acoust
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16.139 A. Eriksson: Aspects of Swed
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Computer 17. Computer Mu Music This
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Quantum step Amplitude Quantization
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Some might notice that linear inter
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pers, textbooks, patents, etc. Furt
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0:00.0 0.5 0 Computer Music 17.3 Ad
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(0,0) (0,1) (1,1) (0,2) (1,2) (0,3)
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synthesizing vocoder. The main diff
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x(n) + z -1 z -1 Scattering junctio
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230 Hz FOF 1100 Hz FOF 1700 Hz FOF
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0 y + - Computer Music 17.8 Physica
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-1 (1-ß )×length Velocity + Veloc
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0 -30 (dB) -60 0 1.5 3 4.5 (kHz) Fi
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17.10 Composition The history of co
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and variance of the features can be
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17.20 J.L. Kelly Jr., C.C. Lochbaum
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Audio 18. Audio and Electroacoustic
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Alexander Graham Bell filed his pat
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on magnetic stripes. A common arran
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60 40 20 0 SPL-sound pressure level
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Interaural intensity difference (dB
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with equalization, without incurrin
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Fig. 18.8 Sine wave with crossover
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18.3.8 Dynamic Range Dynamic range
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Directly actuated type Diaphragm ty
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effective pickup pattern of the arr
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attempts to apply complementary com
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Most of the issues relating to spea
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nificant design considerations. At
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Some appreciation of the performanc
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pre-digital reverberators were elec
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and ‘s’ in English text - may b
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content of rest of the signal spect
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cross the head, in opposite directi
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18.2 J. Sterne: The Audible Past (D
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18.71 T. Sporer: Creating, assessin
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786 Part F Biological and Medical A
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Medical 21. Medical Acous Acoustics
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21.1 Introduction to Medical Acoust
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Auscultation location Right & left
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portance. The Strouhal number has b
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Fig. 21.3 Phono-cardiograph transdu
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Amplitude 8 6 4 2 0 -2 -4 -6 Displa
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λ1 = c1 / fus θ1 λ2 = c2 / fus
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lood flow can be resolved if the si
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vided in the image thickness direct
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not as predicted, because the wave
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Fig. 21.18a,b Quadrature Doppler de
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a) b) c) 100 0 V mV 10 0 a = 13 a =
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Ultrasound contact gel Position enc
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a) 10 cm b) c) 10 cm Fig. 21.32a-c
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a) Pin B Pin A Ultrasound line b) M
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Organ Patient Ultrasound transducer
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systems cannot tell the difference
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40 µm can be resolved. For a 10 kH
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a) b) c) d) Medical Acoustics 21.4
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Fig. 21.54 Doppler spectral wavefor
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10 20 30 10 20 30 Pre-exercise B-mo
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Vibrations in a punctured artery De
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the veins and diffuse into the inte
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21.5.3 Agitated Saline and Patent F
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transported by those cells and/or r
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1 0.8 0.6 0.4 0.2 0 Relative power
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High intensity focused ultrasound h
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a) b) c) Fig. 21.74a-c B-mode imagi
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provided simple metrics for the lik
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thickness of the carotid arteries,
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Structural 22. Structural Acoustics
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Structural Acoustics and Vibrations
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Magnitude (arb. units) 1.4 1.2 1.0
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This does not include the case wher
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the mass matrix is taken to be cons
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Magnitude (dB) -10 -30 -50 0 1 2 3
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where D(ω) = ω 4 − 2iω 3�
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form y(x, t) = � Φn(x)qn(t) . (2
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first to solve the wave equation (2
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5 3 1 -1 -3 -5 0 1 2 3 4 5 6 7 8 9
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conditions at each end) are necessa
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from which we can derive through (2
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In this case, the eigenfrequencies
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of radiation modes and their link w
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Finally, the displacement is ˜ξ(x
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notes the value of this eigenmode a
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Pm = ˙Q H [Rs + Ra] ˙Q , (22.262)
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where and Ra = 2ζaω0 M Z(s) = zL
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Radiated Power. The mean acoustic p
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(22.318) can be written ξ(x, y, t)
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Denoting the eigenfrequencies and e
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Magnitude (arb. units) 3 2 1 0 -1 -
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for any real symmetric tensor Xij.
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F(N) 1 0.5 0 -0.5 -1 -1 -0.8 -0.6 -
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whose solution is θ1 = A cos ωτ.
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4.5 3.5 2.5 1.5 A 0.5 0 0.5 1.0 1.5
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Equations (22.423) are usually writ
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3. As the amplitude reaches the top
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Shallow Spherical Shells and Plates
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22.20 L. Cremer, M. Heckl: Structur
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Noise Noise is discussed in terms o
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where the overbars represent time a
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Typical outdoor setting A-weighted
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90 dB(A)” is widely used, and imp
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Microphone, amplifier and A/D conve
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When each segment of the measuremen
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found from � LW = Lp + 10 log A +
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surement method is the ultimate use
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An intensity analyzer is more compl
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23.2.5 Criteria for Noise Emissions
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Table 23.5 Table of limit values fr
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a) Air flows freely to rotor Weak t
Page 982 and 983:
Static efficiency normalized to its
Page 984 and 985:
ful applications. Good results are
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Table 23.8 Crossover speeds for var
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Reduction of airplane engine noise
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A variety of materials are used to
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∆LF (dB) 0 -10 -20 α -30 0.05 0.
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Absorption coefficient 1.0 0.8 0.6
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high enough that there is little so
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23.4.4 Criteria for Noise Immission
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Table 23.10 (cont.) Some features o
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Noise 23.4 Noise and the Receiver 1
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view of administrative procedures r
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provides recommendations for a foll
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sound power levels of noise sources
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23.68 ISO: ISO 9296:1988 Acoustics
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in impedance tubes - Part 2: Transf
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23.194 Commission of the European C
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1022 Part H Engineering Acoustics P
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Sound 25. Intens Sound Intensity So
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Under such conditions the intensity
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a) Pressure and particle velocity 0
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τ is a dummy time variable. The ca
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Error in intensity (dB) 5 0 -5 -10
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8 7 6 5 4 3 2 1 0 -1 -2 -3 Error du
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crophones are calibrated with a pis
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Sound power level (dB re 1 pW) 72 7
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it is relatively straightforward si
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intensity normal to the source. Thi
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25.9 W. Maysenhölder: The reactive
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25.77 ISO: ISO 11205 Acoustics - No
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Optical 27. Optical Methods Metho f
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course also present in ordinary hol
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Optical Methods for Acoustics and V
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50 100 150 200 250 300 350 400 450
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a) b) Optical Methods for Acoustics
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nm 1000 0 -1000 150 y (mm) 100 50 O
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Laser Optical Methods for Acoustics
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References 27.1 E.F.F. Chladni: Die
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27.75 E.-L.Johansson, L. Benckert,
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About the Authors Iskander Akhatov
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Neville H. Fletcher Chapter F.19 Au
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Brian C. J. Moore Chapter D.13 Univ
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Detailed Contents List of Abbreviat
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3.8.3 Acoustic Power ..............
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4.8.3 Typical Speed of Sound Profil
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7.3 Engines .......................
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10 Concert Hall Acoustics Based on
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13.4 Temporal Processing in the Aud
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15.2.5 String-Bridge-Body Coupling
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19.6 Birds ........................
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22.4.5 Combinations of Elementary S
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24.8 Overall View on Microphone Cal
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Subject Index 3 dB bandwidth 463 A
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British Medical Ultrasound Society
Page 1160 and 1161:
electric circuit analogues - acoust
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hyperspeech 703 hypospeech 703 I IA
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- participation factors 909 - stiff
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- musical instruments 541 - musical
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- nonlinear vibrations 957 - plate
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subjective preference theory 353 su
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Introduction to Acoustics

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