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Line 1: A '''parametric array''', in the field of [[acoustics]], is a nonlinear [[transducer\|transduction]] mechanism that generates narrow, nearly [[side lobe]]-free beams of low frequency sound, through the mixing and interaction of high frequency [[sound wave]]s, effectively overcoming the [[diffraction limit]] (a kind of spatial 'uncertainty principle') associated with linear acoustics.<ref>{{cite book\| last=Beyer\| first=Robert T\| title=Nonlinear Acoustics\| chapter=Preface to the Original Edition\| chapter-url=http://asa.aip.org/books/nonlinear.html#Preface1\|archive-date=February 16, 2018 \|archive-url=https://web.archive.org/web/20180216214423/https://asa.aip.org/books/nonlinear.html#Preface1 \|url-status=dead }}</ref> The main side lobe-free beam of low frequency sound is created as a result of nonlinear mixing of two high frequency sound beams at their difference frequency. Parametric arrays can be formed in water,<ref name=nonlinear-underwater-acoustics-book>{{cite book\| last1=Novikov \| first1=B. K. \| last2=Rudenko \| first2=O. V. \| last3=Timoshenko \| first3=V. I. \| translator= Robert T. Beyer\| title=Nonlinear Underwater Acoustics\| url=http://asa.aip.org/books/nonuw.html \|oclc=16240349 \|isbn=9780883185223 \|publisher=American Institute of Physics \|date=1987}}</ref> air,<ref>{{cite journal \| doi = 10.1121/1.384959 \| volume=68 \| issue=4 \| title=Experimental study of a saturated parametric array in air \| year=1980 \| journal=The Journal of the Acoustical Society of America \| pages=1214–1216 \| last1 = Trenchard \| first1 = Stephen E. \| last2 = Coppens \| first2 = Alan B.\| bibcode=1980ASAJ...68.1214T }}</ref> and earth materials/rock.<ref>{{cite journal \| doi = 10.1121/1.403453 \| volume=91 \| issue=4 \| title=Finite amplitude wave studies in earth materials. \| year=1992 \| journal=The Journal of the Acoustical Society of America \| page=2350 \| last1 = Johnson \| first1 = P. A. \| last2 = Meegan \| first2 = G. D. \| last3 = McCall \| first3 = K. \| last4 = Bonner \| first4 = B. P. \| last5 = Shankland \| first5 = T. J.\| bibcode=1992ASAJ...91.2350J \| doi-access = free }}</ref><ref>[http://www.lanl.gov/orgs/ees/ees11/geophysics/nonlinear/pubs/parabeam.html Parametric Beam Formation in Rock]</ref>▼ ~~{{Citation style\|date=September 2009}}~~ ▲A '''parametric array''', in the field of [[acoustics]], is a nonlinear [[transducer\|transduction]] mechanism that generates narrow, nearly [[side lobe]]-free beams of low frequency sound, through the mixing and interaction of high frequency [[sound wave]]s, effectively overcoming the [[diffraction limit]] (a kind of spatial 'uncertainty principle') associated with linear acoustics.<ref>{{cite book\| last=Beyer\| first=Robert T\| title=Nonlinear Acoustics\| chapter=Preface to the Original Edition\| url=http://asa.aip.org/books/nonlinear.html#Preface1}}</ref> The main side lobe-free beam of low frequency sound is created as a result of nonlinear mixing of two high frequency sound beams at their difference frequency. Parametric arrays can be formed in water,<ref name=nonlinear-underwater-acoustics-book>{{cite book\| last1=Novikov \| first1=B. K. \| last2=Rudenko \| first2=O. V. \| last3=Timoshenko \| first3=V. I. \| translator= Robert T. Beyer\| title=Nonlinear Underwater Acoustics\| url=http://asa.aip.org/books/nonuw.html \|oclc=16240349 \|isbn=9780883185223 \|publisher=American Institute of Physics \|date=1987}}</ref> air,<ref>{{cite journal \| doi = 10.1121/1.384959 \| volume=68 \| title=Experimental study of a saturated parametric array in air \| year=1980 \| journal=The Journal of the Acoustical Society of America \| pages=1214–1216 \| last1 = Trenchard \| first1 = Stephen E. \| last2 = Coppens \| first2 = Alan B.}}</ref> and earth materials/rock.<ref>{{cite journal \| doi = 10.1121/1.403453 \| volume=91 \| title=Finite amplitude wave studies in earth materials. \| year=1992 \| journal=The Journal of the Acoustical Society of America \| page=2350 \| last1 = Johnson \| first1 = P. A. \| last2 = Meegan \| first2 = G. D. \| last3 = McCall \| first3 = K. \| last4 = Bonner \| first4 = B. P. \| last5 = Shankland \| first5 = T. J.}}</ref><ref>[http://www.lanl.gov/orgs/ees/ees11/geophysics/nonlinear/pubs/parabeam.html Parametric Beam Formation in Rock]</ref> == History == Priority for discovery and explanation of the parametric array owes to [[Peter Westervelt\|Peter J. Westervelt]],<ref>[http://scitation.aip.org/getabs/servlet/GetabsServlet?prog=normal&id=JASMAN000119000005003231000004&idtype=cvips&gifs=yes Professor Peter Westervelt and the parametric array]</ref> winner of the [[Lord Rayleigh]] Medal,<ref>[http://www.ioa.org.uk/medals-and-awards/ Institute of Acoustics - Medals & Awards Programme] {{webarchive\|url=https://web.archive.org/web/20090628181721/http://www.ioa.org.uk/medals-and-awards/ \|date=2009-06-28 }}</ref> ~~(currently Professor Emeritus at [[Brown University]]),~~ although important experimental work was contemporaneously underway in the former Soviet Union.<ref name=nonlinear-underwater-acoustics-book /> According to Muir<ref>{{Harvard ~~[16~~citation no brackets\|Muir\|1976}}, p. 554].</ref> and Albers ~~[17]~~,<ref name=":0">{{Harvnb\|Albers\|1972}}</ref> the concept for the parametric array occurred to Dr. Westervelt while he was stationed at the London, England, branch office of the [[Office of Naval Research]] in 1951. According to Albers,<ref ~~[17],~~name=":0" /> he (Westervelt) there first observed an accidental generation of low frequency sound ''in air'' by Captain H.J. Round (British pioneer of the [[superheterodyne receiver]]) via the parametric array mechanism. The phenomenon of the parametric array, seen first experimentally by Westervelt in the 1950s, was later explained theoretically in 1960, at a meeting of the [[Acoustical Society of America]]. A few years after this, a full paper<ref>{{Harvard ~~[2]~~citation no brackets\|Westervelt\|1963}}</ref> was published as an extension of Westervelt's classic work on the nonlinear Scattering of Sound by Sound,.<ref>{{Harvard ascitation ~~described~~no ~~in [8,6,12].~~brackets\|Roy\|Wu\|1993}}</ref><ref>{{Harvnb\|Beyer\|1974}}</ref><ref>{{Harvnb\|Bellin\|Beyer\|1960}}</ref> == Foundations == The foundation for Westervelt's theory of sound generation and scattering in [[nonlinear acoustics\|nonlinear acoustic]]<ref>{{cite journal \| doi = 10.1121/1.380612 \| volume=57 \| issue=6 \| title=The status and future of nonlinear acoustics \| year=1975 \| journal=The Journal of the Acoustical Society of America \| pages=1352–1356 \| last1 = Westervelt \| first1 = Peter J.\| bibcode=1975ASAJ...57.1352W }}</ref> media owes to an application of [[James Lighthill\|Lighthill]]'s ~~equation (see~~ [[Aeroacoustics#Lighthill's equation\|~~Aeroacoustics~~equation]]) for fluid particle motion. The application of Lighthill’s theory to the nonlinear acoustic realm yields the Westervelt–Lighthill Equation (WLE).<ref>[https://dspace.mit.edu/bitstream/1721.1/28762/1/59823423.pdf Sources of Difference Frequency Sound in a Dual-Frequency Imaging System with Implications for Monitoring Thermal Surgery]{{dead link\|date=January 2018 \|bot=InternetArchiveBot \|fix-attempted=yes }}</ref> Solutions to this equation have been developed using [[Green's functions]] ~~[4,5]~~<ref>{{Harvnb\|Moffett\|Mellen\|1977}}</ref><ref>{{Harvnb\|Moffett\|Mellen\|1976}}</ref> and Parabolic Equation (PE) Methods, most notably via the Kokhlov–Zablotskaya–Kuznetzov (KZK) equation.<ref>[{{Cite web\|url=http://people.bu.edu/robinc/kzk/]\|title = Texas KZK Time Domain Code}}</ref> An alternate mathematical formalism using [[Fourier operator]] methods in [[wavenumber]] space, was also developed ~~by Westervelt,~~ and generalized inby ~~[1] for solving the WLE in a most general manner~~Westervelt.<ref>{{Harvnb\|Woodsum\|Westervelt\|1981}}</ref> The solution method is formulated in Fourier (wavenumber) space in a representation related to the beam patterns of the primary fields generated by linear sources in the medium. This formalism has been applied not only to parametric arrays ~~[15]~~,<ref>{{Harvnb\|Woodsum\|2006}}</ref> but also to other nonlinear acoustic effects, such as the absorption of sound by sound and to the equilibrium distribution of [[sound intensity]] spectra in cavities ~~[18]~~.<ref>{{Harvnb\|Cabot\|Putterman\|1981}}</ref> == Applications == Line 26 ⟶ 24: sub-bottom profiling non-destructive testing and 'see through walls' sensing<ref>{{cite journal \| doi = 10.1016/S0041-624X(99)00109-2 \| pmid=11243456 \| volume=37 \| issue=8 \| title=A non-contact technique for evaluation of elastic structures at large stand-off distances: applications to classification of fluids in steel vessels \| year=2000 \| journal=Ultrasonics \| pages=531–536 \| last1 = Kaduchak \| first1 = Gregory \| last2 = Sinha \| first2 = Dipen N. \| last3 = Lizon \| first3 = David C. \| last4 = Kelecher \| first4 = Michael J.\| url=https://zenodo.org/record/1259727 \| doi-access = free }}</ref> remote ocean sensing<ref>{{cite journal \| doi = 10.1121/1.414208 \| volume=98 \| issue=5 \| title=Remote ocean sensing by parametric array \| year=1995 \| journal=The Journal of the Acoustical Society of America \| page=2915 \| last1 = Naugolnykh \| first1 = Konstantin A. \| last2 = Esipov \| first2 = Igor B.\| bibcode=1995ASAJ...98.2915N \| doi-access=free }}</ref> * medical [[ultrasound]]<ref>{{cite journal \| doi = 10.1088/0031-9155/46/11/314 \| pmid=11720358 \| volume=46 \| issue=11 \| title=A focused ultrasound method for simultaneous diagnostic and therapeutic applications—a simulation study \| year=2001 \| journal=Physics in Medicine and Biology \| pages=2967–2984 \| last1 = Konofagou \| first1 = Elisa \| last2 = Thierman \| first2 = Jonathan \| last3 = Hynynen \| first3 = Kullervo\| bibcode=2001PMB....46.2967K \| s2cid=2036873 \| url=https://semanticscholar.org/paper/85b7f120e6568d0a912d79040fd1b0d7810b1053 }}</ref> * and tomography <ref>{{cite journal \|last1=Zhang ~~doi~~\|first1=Dong \|last2=Chen ~~10.1121/1.1344160~~\|first2=Xi \|last3=Xiu-fen ~~volume~~\|first3=~~109~~Gong \|year=2001 \|title=Acoustic nonlinearity parameter tomography for biological tissues via parametric array from a circular piston source—Theoretical analysis and computer simulations \| ~~year=2001 \|~~ journal=The Journal of the Acoustical Society of America \| ~~pages~~volume=~~1219–1225~~109 \| ~~last1~~ issue= ~~Zhang~~3 \| ~~first1~~ pages= ~~Dong~~1219–1225 \| ~~last2~~ bibcode= ~~Chen~~2001ASAJ..109.1219Z \| ~~first2~~ doi= Xi10.1121/1.1344160 \| ~~last3~~ pmid= ~~Xiu-fen \| first3 = Gong~~11303935}} </ref> * underground seismic prospecting<ref>{{cite journal \| doi = 10.1121/1.2022023 \| volume=76 \| issue=S1 \| title=~~High‐resolution~~High-resolution seismic profiling with a ~~low‐frequency~~low-frequency parametric array \| year=1984 \| journal=The Journal of the Acoustical Society of America \| page=S78 \| last1 = Muir \| first1 = T. G. \| last2 = Wyber \| first2 = R. J.\| bibcode=1984ASAJ...76...78M }}</ref> * active noise control<ref>{{cite web \|url=http://www.mecheng.adelaide.edu.au/anvc/abstract.php?abstract=378 \|title=~~Archived~~Active ~~copy~~control of sound using a parametric array \|accessdate=2006-12-05 \|~~deadurl~~url-status=~~yes~~dead \|archiveurl=https://web.archive.org/web/20070309235859/http://www.mecheng.adelaide.edu.au/anvc/abstract.php?abstract=378 \|archivedate=2007-03-09 ~~\|df=~~ }}</ref> * and directional high-fidelity commercial audio systems ([[Sound from ultrasound]])<ref>[[n:Elwood Norris receives 2005 Lemelson-MIT Prize for invention.]]</ref> Parametric ''receiving'' arrays can also be formed for directional reception.<ref>~~[http:/~~{{Cite book \|doi = 10.1109/~~ieeexplore~~ICASSP.~~ieee~~1979.~~org/xpl/freeabs_all~~1170632\|chapter = Experiments with a large aperture parametric acoustic receiving array\|title = ICASSP '79.~~jsp?arnumber~~ IEEE International Conference on Acoustics, Speech, and Signal Processing\|year =~~1170632]~~ 1979\|last1 = Reeves\|first1 = C.\|last2 = Goldsberry\|first2 = T.\|last3 = Rohde\|first3 = D.\|volume = 4\|pages = 616–619}}</ref> In 2005, Elwood Norris won the $500,000 [[Lemelson-MIT Prize\|MIT-Lemelson Prize]] for his application of the parametric array to commercial high-fidelity loudspeakers. ==References== Line 39 ⟶ 37: == Further reading == * ~~[1]~~ {{Wikicite\|reference=H.C. Woodsum and P.J. Westervelt, "A General Theory for the Scattering of Sound by Sound", Journal of Sound and Vibration (1981), 76(2), 179-186.\|ref=CITEREFWoodsumWestervelt1981}} * ~~[2]~~ {{Wikicite\|reference=Peter J. Westervelt, "Parametric Acoustic Array", Journal of the Acoustical Society of America, Vol. 35, No. 4 (535-537), 1963\|ref=CITEREFWestervelt1963}} * ~~[5]~~ {{Wikicite\|reference=Mark B. Moffett and Robert H. Mellen, "OnModel for Parametric ~~Source Aperture Factors~~Sources", J. Acoust. Soc. Am. Vol. 6061, No. 32, ~~Sept~~Feb. ~~1976~~1977\|ref=CITEREFMoffettMellen1977}}▼ * [3] * ~~[4]~~ {{Wikicite\|reference=Mark B. Moffett and Robert H. Mellen, "~~Model for~~On Parametric ~~Sources~~Source Aperture Factors", J. Acoust. Soc. Am. Vol. 6160, No. 23, ~~Feb~~Sept. ~~1977~~1976\|ref=CITEREFMoffettMellen1976}} * ~~[6]~~ {{Wikicite\|reference=Ronald A. Roy and Junru Wu, "An Experimental Investigation of the Interaction of Two Non-Collinear Beams of Sound", Proceedings of the 13th International Symposium on Nonlinear Acoustics, H. Hobaek, Editor, Elsevier Science Ltd., London (1993)\|ref=CITEREFRoyWu1993}}▼ ▲* [5] Mark B. Moffett and Robert H. Mellen, "On Parametric Source Aperture Factors", J. Acoust. Soc. Am. Vol. 60, No. 3, Sept. 1976 * ~~[7]~~ Harvey C. Woodsum, "Analytical and Numerical Solutions to the 'General Theory for the Scattering of Sound by Sound”, J. Acoust. Soc. Am. Vol. 95, No. 5, Part 2 (2PA14), June, 1994 (Program of the 134th Meeting of the Acoustical Society of America, Cambridge Massachusetts)▼ ▲* [6] Ronald A. Roy and Junru Wu, "An Experimental Investigation of the Interaction of Two Non-Collinear Beams of Sound", Proceedings of the 13th International Symposium on Nonlinear Acoustics, H. Hobaek, Editor, Elsevier Science Ltd., London (1993) * ~~[8]~~ {{Wikicite\|reference=Robert T. Beyer, Nonlinear Acoustics, 1st Edition (1974),. Published by the Naval Sea Systems Command.\|ref=CITEREFBeyer1974}}▼ ▲* [7] Harvey C. Woodsum, "Analytical and Numerical Solutions to the 'General Theory for the Scattering of Sound by Sound”, J. Acoust. Soc. Am. Vol. 95, No. 5, Part 2 (2PA14), June, 1994 (Program of the 134th Meeting of the Acoustical Society of America, Cambridge Massachusetts) * ~~[9]~~ H.O. Berktay and D.J. Leahy, Journal of the Acoustical Society of America, 55, p. 539 (1974)▼ ▲* [8] Robert T. Beyer, Nonlinear Acoustics, 1st Edition (1974),. Published by the Naval Sea Systems Command. * ~~[11]~~ M.J. ~~Lighhill~~Lighthill, ~~“On~~"On Sound Generated Aerodynamically”, Proc. R. Soc. Lond. ~~A222~~A211, 1564-32687 (~~1954~~1952)▼ ▲* [9] H.O. Berktay and D.J. Leahy, Journal of the Acoustical Society of America, 55, p. 539 (1974) * ~~[10]~~ M.J. Lighthill, ~~"On~~“On Sound Generated Aerodynamically”, Proc. R. Soc. Lond. ~~A211~~A222, ~~564~~1-~~687~~32 (~~1952~~1954) * ~~[12]~~ {{Wikicite\|reference=J.S. Bellin and R. T. Beyer, “Scattering of Sound by Sound”, J. Acoust. Soc. Am. 32, 339-341 (1960)\|ref=CITEREFBellinBeyer1960}}▼ ▲* [11] M.J. Lighhill, “On Sound Generated Aerodynamically”, Proc. R. Soc. Lond. A222, 1-32 (1954) * ~~[13]~~ M.J. Lighthill, Math. Revs. 19, 915 (1958)▼ ▲* [12] J.S. Bellin and R. T. Beyer, “Scattering of Sound by Sound”, J. Acoust. Soc. Am. 32, 339-341 (1960) * ~~[14]~~ H.C. Woodsum, Bull. Of Am. Phys. Soc., Fall 1980; “A Boundary Condition Operator for Nonlinear Acoustics”▼ ▲* [13] M.J. Lighthill, Math. Revs. 19, 915 (1958) * ~~[15]~~ {{Wikicite\|reference=H.C. Woodsum, Proc. 17th International Conference on Nonlinear Acoustics, AIP Press (NY), 2006; " Comparison of Nonlinear Acoustic Experiments with a Formal Theory for the Scattering of Sound by Sound", paper TuAM201.\|ref=CITEREFWoodsum2006}}▼ ▲* [14] H.C. Woodsum, Bull. Of Am. Phys. Soc., Fall 1980; “A Boundary Condition Operator for Nonlinear Acoustics” * ~~[16]~~ {{Wikicite\|reference=T.G. Muir, Office of Naval Research Special Report - "Science, Technology and the Modern Navy, Thirtieth Anniversary (1946-1976), Paper ONR-37, "Nonlinear Acoustics: A new Dimension in Underwater Sound", published by the Department of the Navy (1976)\|ref=CITEREFMuir1976}}▼ ▲* [15] H.C. Woodsum, Proc. 17th International Conference on Nonlinear Acoustics, AIP Press (NY), 2006; " Comparison of Nonlinear Acoustic Experiments with a Formal Theory for the Scattering of Sound by Sound", paper TuAM201. * ~~[17]~~ {{Wikicite\|reference=V.M. Albers,"Underwater Sound, Benchmark Papers in Acoustics, p.415; Dowden, Hutchinson and Ross, Inc., Stroudsburg, PA (1972)\|ref=CITEREFAlbers1972}}▼ ▲* [16] T.G. Muir, Office of Naval Research Special Report - "Science, Technology and the Modern Navy, Thirtieth Anniversary (1946-1976), Paper ONR-37, "Nonlinear Acoustics: A new Dimension in Underwater Sound", published by the Department of the Navy (1976) * ~~[18]~~ {{Wikicite\|reference=M. Cabot and Seth Putterman, "Renormalized Classical Non-linear Hydrodynamics, Quantum Mode Coupling and Quantum Theory of Interacting Phonons", Physics Letters Vol. 83A, No. 3, 18 May 1981, pp.~~ ~~ 91–94 (North Holland Publishing Company-Amsterdam)\|ref=CITEREFCabotPutterman1981}}▼ ▲* [17] V.M. Albers,"Underwater Sound, Benchmark Papers in Acoustics, p.415; Dowden, Hutchinson and Ross, Inc., Stroudsburg, PA (1972) * ~~[19]~~ Nonlinear Parameter Imaging Computed Tomography by Parametric Acoustic Array Y. Nakagawa; M. Nakagawa; M. Yoneyama; M. Kikuchi. IEEE 1984 Ultrasonics Symposium. Volume, Issue, 1984 Page(s):673–676▼ ▲* [18] M. Cabot and Seth Putterman, "Renormalized Classical Non-linear Hydrodynamics, Quantum Mode Coupling and Quantum Theory of Interacting Phonons", Physics Letters Vol. 83A, No. 3, 18 May 1981, pp. 91–94 (North Holland Publishing Company-Amsterdam) * Active Nonlinear Acoustic Sensing of an Object with Sum or Difference Frequency Fields. Zhang, W.; Liu, Y.; Ratilal, P.; Cho, B.; Makris, N.C.; Remote Sens. 2017, 9, 954. https://doi.org/10.3390/rs9090954 ▲* [19] Nonlinear Parameter Imaging Computed Tomography by Parametric Acoustic Array Y. Nakagawa; M. Nakagawa; M. Yoneyama; M. Kikuchi. IEEE 1984 Ultrasonics Symposium. Volume, Issue, 1984 Page(s):673–676 {{DEFAULTSORT:Parametric Array}}