Introduction to Acoustics

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664 Part E Music, Speech, Electroacoustics Part E 15 (1974), English translation in J. Guitar Acoustics No.5, 19 (1982) 15.99 Q. Christensen: Qualitative models for low frequency guitar function, J. Guitar Acoust. 6, 10–25 (1982) 15.100 T.D. Rossing, J. Popp, D. Polstein: Acoustical Response of Guitars. SMAC 83 (Royal Swedish Academy of Music, Stockholm 1985) pp. 311–332 15.101 E.V. Jansson: On higher air modes in the violin, Catgut Acoust. Soc. Newsletter 19, 13–15 (1973), Reprinted in Musical Acoustics, Part 2, ed. C.M.Hutchins (Dowden, Hutchinson & Ross, Stroudsberg 1976) 15.102 G. Derveaux, A. Chaigne, P. Joly, J. Bécache: Timedomain simulation of guitar: Model and method, J. Acoust. Soc. Am. 114, 3368–3383 (2003) 15.103 G. Roberts, G. Finite: Element analysis of the violin, PhD Thesis (Cardiff University, Cardiff 1986), extract reproduced in Hutchins and Benade 15.27, pp.575- 590 15.104 B.E. Richardson, G.W. Roberts: The adjustment of mode frequencies in guitars: A study by means of holographic and finite element analysis. Proc. SMAC. 83 (Royal Swedish Academy of Music, Stockholm 1985) pp. 285–302 15.105 G. Derveaux, A. Chaigne, P. Joly, J. Bécache: Numerical simulation of the acoustic guitar (INRIA, Rocquencourt 2003), from http://www.inria.fr/multimedia/Videotheque-fra. html 15.106 G. Bissinger: A unified materials-normal mode approach to violin acoustics, Acustica 91, 214–228 (2005) 15.107 M. Schleske: On making "tonal copies" of a violin, J. Catgut Acoust. Soc. 3(2), 18–28 (1996) 15.108 L.S. Morset: A low-cost pc-based tool for violin acoustics measurements, ISMA 2001 (Fondazione Scuola Di San Giorgio, Venice 2001) pp. 627–630 15.109 H.O. Saldner, N.-E. Molin, E.V. Jansson: Vibrational modes of the violin forced via the bridge and action of the soundpost, J. Acoust. Soc. Am. 100, 1168–1177 (1996) 15.110 E.V. Jansson, N.-E. Molin, H. Sundin: Resonances of a violin body studied by hologram interferometry and acoustical methods, Phys. Scipta 2, 243–256 (1970) 15.111 N.-E. Molin, A.O. Wählin, E.V. Jansson: Transient response of the violin, J. Acoust. Soc. Am. 88,2479– 2481 (1990) 15.112 N.-E. Molin, A.O. Wählin, E.V. Jansson: Transient response of the violin revisited, J. Acoust. Soc. Am. 90, 2192–2195 (1991) 15.113 J. Curtin: Innovation in violin making, Proc. Int. Symp. Musical Acoustics, CSA-CAS 1, 11–16 (1998) 15.114 J. Meyer: Directivity of the bowed string instruments and its effect on orchestral sound in concert halls, J. Acoust. Soc. Am. 51, 1994–2009 (1972) 15.115 G. Weinreich, E.B. Arnold: Method for measuring acoustic fields, J. Acoust. Soc. Am. 68, 404–411 (1982) 15.116 G. Weinreich: Sound hole sum rule and dipole moment of the violin, J. Acoust. Soc. Am. 77, 710–718 (1985) 15.117 T.J.W. Hill, B.E. Richardson, S.J. Richardson: Acoustical parameters for the characterisation of the classical guitar, Acustica 89, 335–348 (2003) 15.118 G. Bissinger, A. Gregorian: Relating normal mode properties of violins to overall quality signature modes, Catgut Acoust. Soc. J. 4(8), 37–45 (2003) 15.119 E.V. Jansson: Admittance measurements of 25 high quality violins, Acustica 83, 337–341 (1997) 15.120 G. Weinreich: Directional tone colour, J. Acoust. Soc. Am. 101, 2338–2346 (1997) 15.121 J. Meyer: Zur klangichen Wirkung des Streicher- Vibratos, Acustica 76, 283–291 (1992) 15.122 H. Fletcher, L.C. Sanders: Quality of violin vibrato tones, J. Acoust. Soc. Am. 41, 1534–1544 (1967) 15.123 M.V. Matthews, K. Kohut: Electronic simulation of violin resonances, J. Acoust. Soc. Am. 53,1620–1626 (1973) 15.124 J. Nagyvary: Modern science and the classical violin, Chem. Intel. 2, 24–31 (1996) 15.125 L. Burckle, H. Grissino-Mayer: Stradivari, violins, tree rings and the Maunder minimum, Dendrichronologia 21, 41–45 (2003) 15.126 C.M. Hutchins: A 30-year experiment in the acoustical and musical development of violin family instruments, J. Acoust. Soc. Am. 92, 639–650 (1992), 15.127 H.L.F. Helmholtz: On the Sensations of Tone, 4th edn. (Dover, New York 1954), trans. by A.J. Ellis 15.128 H. Bouasse: Instruments á Vent (Delagrave, Paris 1929) 15.129 M. Campbell, C. Greated: The Musicians Guide to Acoustics (Oxford Univ. Press, Oxford 1987) 15.130 C.J. Nederveen: Acoustical Aspects of Woodwind Instruments (Northern Illinois Univ. Press, DeKalb 1998) 15.131 A. Hirschberg, J. Kergomard, G. Weinreich: Mechanics of Musical Instruments (Springer, Berlin, New York 1995) 15.132 J. Backus: The Acoustical Foundations of Music,2nd edn. (Norton, New York 1977) 15.133 A.H. Benade: Fundamentals of Musical Acoustics (Oxford Univ. Press, Oxford 1975) 15.134 D.M. Campbell (Ed.): Special Issue on Musical Wind Instruments Acoustics, Acustica 86(4), 599–755 (2000) 15.135 P.M. Moorse, K.U. Ingard: Theoretical Acoustics (McGraw–Hill, New York 1968), reprinted by Princeton Univ. Press, Princeton (1986) 15.136 L.L. Beranek: Acoustics (McGraw Hill, New York 1954) pp. 91–115, reprinted by Acoust. Soc. Am. (1986)
15.137 H. Levine, L. Schwinger: On the radiation of sound from an unflanged pipe, Phys. Rev. 73, 383–406 (1948) 15.138 R.D. Ayers, L.J. Eliason, D. Mahrgereth: The conical bore in musical acoustics, Am. J. Phys. 53, 528–527 (1985) 15.139 H.F. Olson: Acoustic Engineering (Van Nostrand- Reinhold, Princeton 1957) pp. 88–123 15.140 L.E. Kinsler, A.R. Frey, A.B. Coppens, J.V. Sanders: Fundamentals of Acoustics (Wiley, New York 1982), Fig. 14.19 15.141 A.G. Webster: Acoustical impedance, and the theory of horns and the phonograph, Proc. Nat. Acad. Sci. (US) 5, 275–282 (1919) 15.142 C.J. Nederveen: Acoustical Aspects of Woodwind Instruments (Knuf, Amsterdam 1969) p. 60 15.143 D.H. Keefe, A.H. Benade: Wave propagation in strongly curved ducts, J. Acoust. Soc. Am. 74, 320– 332 (1983) 15.144 R. Caussé, J. Kergomard, X. Luxton: Input impedance of brass instruments – Comparison between experiment and numerical models, J. Acoust. Soc. Am. 75, 241–254 (1984) 15.145 N.H. Fletcher, R.K. Silk, L.M. Douglas: Acoustic admittance of air-driven reed generators, Acustica 50, 155–159 (1982) 15.146 A. Almeida, C. Verges, R. Caussé: Quasistatic nonlinear characteristics of double-reed instruments, J. Acoust. Soc. Am. 121, 536–546 (2007) 15.147 S. Ollivier, J.-P. Dalmont: Experimental investigation of clarinet reed operation, SMAC 03 (Royal Swedish Academy of Music, Stockholm 2003) pp. 283–289 15.148 J.-P. Dalmont, J. Gilbert, S. Ollivier: Nonlinear characteristics of single-reed instruments: Quasistatic flow and reed opening measurements, J. Acoust. Soc. Am. 114, 2253–2262 (2003) 15.149 J. Backus, C.J. Nederveen: Acoustical Aspects of Woodwind Instruments (Knuf, Amsterdam 1969) pp. 28–37 15.150 S. Ollivier, J.-P. Dalmont: Experimental investigation of clarinet reed operation, Proc. SMAC 03 (Royal Swedish Academy of Music, Stockholm 2003) pp. 283–289 15.151 A.P.J. Wijnands, A. Hirschberg: Effect of pipeneck downstream of a double reed. In: Proc. Int. Symp. Musical Acoustics (IRCAM, Paris 1995) pp. 148–151 15.152 N.H. Fletcher: Excitation mechanisms in woodwind and brass instruments, Acustica 43, 63–72 (1979), erratum Acustica 50, 155-159 (1982) 15.153 P.D. Koopman, C.D. Hanzelka, J.P. Cottingham: Frequency and amplitude of vibration of reeds from American reed organs as a function of pressure,J.Acoust.Soc.Am.99, 2506 (1996) 15.154 J.-P. Dalmont, J. Gilbert, J. Kergomard: Reed instruments, from small to large amplitude periodic oscillations and the Helmholtz motion analogy, Acustica 86, 671–684 (2000) Musical Acoustics References 665 15.155 J. Backus: Vibrations of the reed and air column of the clarinet, J. Acoust. Soc. Am. 33, 806–809 (1961) 15.156 N.H. Fletcher: Nonlinear theory of musical wind instruments, Appl. Acoust. 30, 85–115 (1990) 15.157 R.T. Schumacher: Self-sustained oscillations of a clarinet; an integral equation approach, Acustica 40, 298–309 (1978) 15.158 R.T. Schumacher: Ab initio calculations of the oscillations of a clarinet, Acustica 48, 71–85 (1981) 15.159 J. Gilbert, J. Kergomard, E. Ngoya: Calculation of steady state oscillations of a clarinet using the harmonic balance technique, J. Acoust. Soc. Am. 86, 35–41 (1989) 15.160 D.M. Campbell: Nonlinear dynamics of musical reed and brass wind instruments, Contemp. Phys. 40, 415–431 (1999) 15.161 N. Gand, J. Gilbert, F. Lalöe: Oscillation threshold of wood-wind instruments, Acta Acustica 1, 137–151 (1997) 15.162 J.-P. Dalmont, J. Kergomard: Elementary model and experiments for the Helmholtz motion of single reed wind instruments. In: Proc. Int. Symp. Mus. Acoust. (IRCAM, Paris 1995) pp. 115– 120 15.163 A.H. Benade: Air column reed and player’s windway interaction in musical instruments. In: Vocal Fold Physiology, Biomechanics, Acoustics and Phonatory Control, ed. by I.R. Titze, R.C. Scherer (Denver Centre for the Performing Arts, Denver 1985) pp. 425–452 15.164 G.P. Scavone: Modelling vocal tract influence in reed wind instruments, Proc. SMAC 03 (Royal Swedish Academy of Music, Stockholm 2003) pp. 291–294 15.165 N.H. Fletcher: Mode locking in non-linearly excited inharmonic musical oscillators, J. Acoust. Soc. Am. 64, 1566–1569 (1978) 15.166 D. Ayers: Basic tests for models of the lip reed, ISMA 2001 (Fondazione Scuola Di San Giorgio, Venice 2001) pp. 83–86 15.167 S.J. Elliot, J.M. Bowsher: Regeneration in brass wind instruments, J. Sound Vibrat. 83, 181–207 (1982) 15.168 F.C. Chen, G. Weinreich: Nature of the lip-reed, J. Acoust. Soc. Am. 99, 1227–1233 (1996) 15.169 S. Adachi, M. Sato: Trumpet sound simulation using a two-dimensional lip vibration model, J. Acoust. Soc. Am. 99, 1200–1209 (1996) 15.170 I.R. Titze: The physics of small-amplitude oscillation of the vocal folds, J. Acoust. Soc. Am. 83, 1536–1552 (1988) 15.171 D.C. Copley, W.J. Strong: A stroboscopic study of lip vibrations in a trombone, J. Acoust. Soc. Am. 99, 1219–1226 (1996) 15.172 S. Yoshikawa, Y. Muto: Brass player’s skill and the associated li-p wave propagation, ISMA 2001 (Fondazione Scuola Di San Giorgio, Venice 2002) pp. 91–949 Part E 15
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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
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Table 11.7 Generalized noise reduct
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Masking sound pressure level (dB) 5
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As for the room criterion (RC) meth
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11.5 Noise Control Methods for Buil
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Neoprene pads (30 durometer) with a
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Concrete Caulk around perimeter Vib
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Trim board to conceal gap (fasten o
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Gypsum board partition (as schedule
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Double-layer ribbed or waffle neopr
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11.6 Acoustical Privacy in Building
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Table 11.9 AI,SIIandPIforopenplanof
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Electronic sound masking in plenum
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E 1179 Standard Specification for S
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430 Part D Hearing and Signal Proce
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Psychoacoust 13. Psychoacoustics Ps
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Absolute threshold (dB SPL) 100 90
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the signal. By using this off-cente
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is as a crude indicator of the exci
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Relative response (dB) 100 90 80 70
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In a variation of this procedure, t
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Level of matching noise (dB) 100 90
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13.4 Temporal Processing in the Aud
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Most models include an initial stag
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The components were either uniforml
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(Frequency DL)/ERBN 0.2 0.1 0.05 0.
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elaborate place models have been pr
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13.6 Timbre Perception 13.6.1 Time-
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the duplex theory of sound localiza
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harmonic (by shifting the frequency
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sive. While some studies have been
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sentences (see Fig. 13.20). They va
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components is usually only perceive
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References 13.1 ISO 389-7: Acoustic
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13.74 D. Ronken: Monaural detection
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asymmetric function, J. Acoust. Soc
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13.211 J. Vliegen, A.J. Oxenham: Se
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534 Part E Music, Speech, Electroac
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Page 618 and 619: 614 Part E Music, Speech, Electroac
Page 672 and 673: The 16. The Human Human Voice in Sp
Page 674 and 675: uation, the effect of gravity is in
Page 676 and 677: piratory muscles (the internal inte
Page 678 and 679: Mean Ps (cm H2O) 50 40 30 20 10 0 D
Page 680 and 681: Glottal flow Closed Opening Open Cl
Page 682 and 683: Transglottal airflow (l/s) 0.4 0.2
Page 684 and 685: Mean spectrum level (dB) -30 -40 -5
Page 686 and 687: 20 10 0 -10 -20 -30 -40 -50 0 i y u
Page 688 and 689: Mean level (dB) 0 -10 -20 -30 -40 1
Page 690 and 691: This topic was addressed by Ladefog
Page 692 and 693: Fig. 16.29 Acoustic consequences of
Page 694 and 695: Bass i e u Alto Tenor o ε œ æ Th
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Page 710 and 711: 16.7 P. Ladefoged, M.H. Draper, D.
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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
Page 906 and 907:
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
Page 914 and 915:
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)
Page 932 and 933:
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 -
Page 942 and 943:
for any real symmetric tensor Xij.
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F(N) 1 0.5 0 -0.5 -1 -1 -0.8 -0.6 -
Page 946 and 947:
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
Page 964 and 965:
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
Page 970 and 971:
found from � LW = Lp + 10 log A +
Page 972 and 973:
surement method is the ultimate use
Page 974 and 975:
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
Page 980 and 981:
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
Page 986 and 987:
Table 23.8 Crossover speeds for var
Page 988 and 989:
Reduction of airplane engine noise
Page 990 and 991:
A variety of materials are used to
Page 992 and 993:
∆LF (dB) 0 -10 -20 α -30 0.05 0.
Page 994 and 995:
Absorption coefficient 1.0 0.8 0.6
Page 996 and 997:
high enough that there is little so
Page 998 and 999:
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
Page 1006 and 1007:
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
Page 1050 and 1051:
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
Page 1056 and 1057:
8 7 6 5 4 3 2 1 0 -1 -2 -3 Error du
Page 1058 and 1059:
crophones are calibrated with a pis
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Sound power level (dB re 1 pW) 72 7
Page 1062 and 1063:
it is relatively straightforward si
Page 1064 and 1065:
intensity normal to the source. Thi
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25.9 W. Maysenhölder: The reactive
Page 1068 and 1069:
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
Page 1104 and 1105:
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
Page 1114 and 1115:
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
Page 1132 and 1133:
Neville H. Fletcher Chapter F.19 Au
Page 1134 and 1135:
Brian C. J. Moore Chapter D.13 Univ
Page 1136 and 1137:
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
Page 1142 and 1143:
7.3 Engines .......................
Page 1144 and 1145:
10 Concert Hall Acoustics Based on
Page 1146 and 1147:
13.4 Temporal Processing in the Aud
Page 1148 and 1149:
15.2.5 String-Bridge-Body Coupling
Page 1150 and 1151:
19.6 Birds ........................
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22.4.5 Combinations of Elementary S
Page 1154 and 1155:
24.8 Overall View on Microphone Cal
Page 1156 and 1157:
Subject Index 3 dB bandwidth 463 A
Page 1158 and 1159:
British Medical Ultrasound Society
Page 1160 and 1161:
electric circuit analogues - acoust
Page 1162 and 1163:
hyperspeech 703 hypospeech 703 I IA
Page 1164 and 1165:
- participation factors 909 - stiff
Page 1166 and 1167:
- musical instruments 541 - musical
Page 1168 and 1169:
- nonlinear vibrations 957 - plate
Page 1170 and 1171:
subjective preference theory 353 su
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