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[APA format] Acoustics and Psycho-Acoustics References

This is a list of references related to acoustics and psycho-acoustics that are cited throughout Flutopedia.

The references on this page are a sub-set of the complete list of Flutopedia references.

For information on the format and other details of these citations, see the main references page.

[APA format] Acoustics and Psycho-Acoustics References

[Allen-SA 1916] Allen, H. S., & Moore, H. (1916). A text-book of practical physics. Macmillan Publishing Ltd.

[Backus 1964] Backus, J. (1964). Effect of wall material on the steady-state tone quality of woodwind instruments, Journal of the Acoustical Society of America, 36(10), 1881–1887, doi:10.1121/1.1919286.

[Barbour 1951] Barbour, J. M. (1951). Tuning and temperament: A historical survey. East Lansing, Michigan: Michigan State College Press. Publication tuningtemperamen00barb on Archive.org (open access).

[Benade 1967] Benade, A. H., & Jansson, F. (1967). An informal preliminary report on the acoustics of brass instrument bores (chiefly on the wave equations in theory and experiment).

[Benade 1977] Benade, A. H. (1977). Acoustical evolution of wind instruments — A course (Physics 323) taught by A. H. Benade in the fall of 1977, Case Western University, Cleveland, Ohio.

[Benade 1990] Benade, A. H. (1990). Fundamentals of musical acoustics, Second, Revised Edition. New York: Dover Publications, Inc.

[Blanc 2010] Blanc, F., Fabre, B., Montgermont, N., Cuadra, P. D. L., & Almeida, A. (2010). Scaling of flute-like instruments: An analysis from the point of view of the hydrodynamic instability of the jet, Acta Acustica united with Acustica, 96(4), 642–653, doi:10.3813/AAA.918319.

[Bruno 2006] Bruno, T. J., & Svoronos, P. D. N. (2006). CRC handbook of fundamental spectroscopic correlation charts. CRC Press.

[Canright 1985] Canright, D. (1985). Pentatonics I have known, 1/1, the Journal of the Just Intonation Network, 1(2), retrieved January 28, 2015.

[Carlos 1996] Carlos, W. (1996). Three asymmetric divisions of the octave.

[Coltman 1968] Coltman, J. W. (1968). Sounding mechanism of the flute and organ pipe, Journal of the Acoustic Society of America, 44, 983–992, doi:10.1121/1.1911240.

[Coltman 1971] Coltman, J. W. (1971). Effect of material on flute tone quality, Journal of the Acoustical Society of America, 49(2), 520–523.

[Coltman 1973] Coltman, J. W. (1973). Material used in flute construction, Woodwind World, 12(1), 20–21.

[Cook 2014] Cook, P. R., & Trueman, D. (2014). Spherical radiation from stringed instruments: Measured, modeled, and reproduced.

[Cramer 1993] Cramer, O. (1993). The variation of the specific heat ratio and the speed of sound in air with temperature, pressure, humidity, and co__sub__2__end_sub__ concentration, Journal of the Acoustic Society of America, 93(5), 2510–2516, doi:10.1121/1.405827.

[Dean 1979] Dean, E. A. (1979). Atmospheric effects on the speed of sound. US Army Electronics Research and Development Command, Atmospheric Sciences Laboratory.

[Deutsch 1975] Deutsch, D. (1975). Two-channel listening to musical scales, Journal of the Acoustical Society of America, 57(5), 1156–1160, doi:10.1121/1.380573.

[Deutsch 2006] Deutsch, D. (2006). The enigma of absolute pitch, Acoustics Today, 2(4), 11–18, doi:10.1121/1.2961141.

[Deutsch 2008] Deutsch, D., Dooley, K., & Henthorn, T. (2008). Pitch circularity from tones comprising full harmonic series, Journal of the Acoustical Society of America, 124(1), 589–597, doi:10.1121/1.2931957.

[Deutsch 2010] Deutsch, D. (2010). The paradox of pitch circularity, Acoustics Today, 6(3), 8–15, doi:10.1121/1.3488670.

[Dodge-ES 1945] Dodge, E. S. (1945). The acoustics of three Maori flutes, Journal of the Polynesian Society, 54(1), 39–61. Publication 20702995 on JSTOR (subscription access).

[Everest 2001] Everest, F. A. (2001). The master handbook of acoustics. New York: McGraw-Hill.

[Fastl 2007] Fastl, H., & Zwicker, E. (2007). Psychoacoustics: Facts and models, Third Edition, Springer Series in Information Sciences, Volume 22. Springer.

[Fletcher-NH 1994] Fletcher, N. H. (1994). Acoustic and aerodynamic determinants of the sound quality of flutes, Meeting of the Acoustical Society of America, Cambridge, Massachussets, June 6–10, 1994.

[Fletcher-NH 1999a] Fletcher, N. H. (1999). The nonlinear physics of musical instruments, Rep. Prog. Phys, 62, 723–764.

[Forinash 2015] Forinash, K. (2015). An interactive ebook on the physics of sound. Indiana University Southeast, retrieved January 28, 2015.

[Forster 2010] Forster, C. (2010). Musical mathematics — On the art and science of acoustic instruments. San Francisco, California: Chronicle Books.

[Fullekrug 2010] Füllekrug, M. (2010). Magnetic activity and Schumann resonance. Northern California Earthquake Data Center, retrieved December 15, 2010.

[Giatti 2001] Giatti, A., & Miniati, M. (2001). Acoustics and its instruments «l'acustica e i suoi strumenti». Giunti Industrie Grafiche S.p.A., in Italian and English.

[Hagerman 1980] Hagerman, B., & Sundberg, J. (1980). Fundamental frequency adjustment in barbershop singing, Journal of Research in Singing, 4(1), 3–17.

[Heathwaite 2010] Heathwaite, A. (2010). Gallery of just intervals, retrieved January 28, 2015.

[Heathwaite 2011] Heathwaite, A. (2011). Overtone scales, retrieved January 28, 2015.

[Helmholtz 1912] Helmholtz, H. L. F., & M.D.; Ellis, A. J. (translator) (1912). On the sensations of tone as a physiological basis for the theory of music, Fourth Edition. London, New York, Bombay, and Calcutta: Longmans, Green, and Co. translated from the Fourth German edition of 1877. First German Edition published in 1863.

[Hirschberg 1999] Hirschberg, A. (1999). Luchtwervels in een blokfluit «Air vortices in a recorder», in Dutch, retrieved September 28, 2010.

[Jing 2003] Jing, M. (2003). A theoretical study of the vibration and acoustics of Ancient Chinese bells, Journal of the Acoustic Society of America, 114(3), 1622–1628, doi:10.1121/1.1600727. Publication 14514215 on PubMed/NCBI (subscription access).

[Lefebvre 2010] Lefebvre, A. (2010). Computational acoustic methods for the design of woodwind instruments (Ph.D. dissertation, McGill University, Montreal, Quebec, Canada).

[Lefebvre 2011] Lefebvre, A., & Scavone, G. P. (2011). On the bore shape of conical instruments, Canadian Acoustics / Acoustique canadienne, 39(3), 128–129.

[Lefebvre 2012] Lefebvre, A., & Scavone, G. P. (2012). Characterization of woodwind instrument toneholes with the finite element method, Journal of the Acoustical Society of America, 131(4), 3153–3163, doi:10.1121/1.3685481. Publication 22501087 on PubMed/NCBI (subscription access).

[Lefebvre 2013] Lefebvre, A., Scavone, G. P., & Kergomard, J. (2013). External tonehole interactions in woodwind instruments, Acta Acustica united with Acustica, 99, 975–985. Publication 1207.5490 on Archive.org (open access).

[Lewis-P 1998] Lewis, P. (1998). Understanding temperaments, Version 1.2.

[Mather-R 1972] Mather, R. (1972). The influence of tube material and thickness on flute tone quality, Woodwind World.

[McGlade 2004] McGlade, J., Yang, H., & Pasko, V. P. (2004). Effects of solar flares on the First Schumann resonance frequency, NSF EE REU PENN STATE Annual Research Journal, 2, 42–51.

[McIntyre 1983] McIntyre, M. E., Schumacher, R. T., & Woodhouse, J. (1983). On the oscillations of musical instruments, Journal of the Acoustical Society of America, 74(5), 1325–1345.

[Messiaen 1944] Messiaen, O.; Satterfield, J. (translation) (1944). The technique of my musical language — La technique de mon langage musical. Paris, France: Alfonse Leduc.

[Miller-DC 1909] Miller, D. C. (1909). The influence of the material of wind-instruments on the tone quality, Science, 29(735), 161–171. Publication 1636184 on JSTOR (subscription access). Publication jstor-1636184 on Archive.org (open access).

[Monzo 2004] Monzo, J. L. (2004). The measurement of Aristoxenus's divisions of the tetrachord.

[Nickolaenko 2002] Nickolaenko, A. P., & Hayakawa, M. (2002). Resonances in the Earth-ionosphere cavity, Modern approaches in geophysics, Volume 19. Springer.

[Ondraskova 2009] Ondraskova, A., Sevcik, S., & Kostecky, P. (2009). A significant decrease of the fundamental Schumann resonance frequency during the solar cycle minimum of 2008–9 as sbserved at Modra Observatory, Contributions to Geophysics and Deodesy, 39(4), 345–354.

[Parncutt 2001] Parncutt, R. Critical comparison of acoustical and perceptual theories of the origin of musical scales, Proceedings of the International Symposium of Musical Acoustics, Perugia, Italy.

[Polk 1983] Polk, C. (1983). Natural and man-made noise in the Earth — Ionosphere cavity at extremely low frequencies, Space Science Reviews, 35(1), 83–89, doi:10.1007/BF00173695.

[Prairie 2006] Prairie, M. (2006). Understanding the acoustics of the Native American-style flute.

[Prairie 2011] Prairie, M. (2011). Back pressure.

[Prairie 2014] Prairie, M. (2014). Nodal interference.

[Price 2010] Price, L. P. (2010). How I make flutes today, Voice of the Wind, 2010(1).

[Price 2011] Price, L. P. (2011). Flute physics.

[Rawcliffe 1992] Rawcliffe, S. (1992). Complex acoustics in Pre-Columbian flute systems, Experimental Musical Instruments, 8(2).

[Rawcliffe 1992a] Rawcliffe, S. (1992). Complex acoustics in Pre-Columbian flute systems, contained in [Robertson 1992], 35–63. cassette number 8. Also published in the Journal of the National Council on Education in the Ceramic Arts, Volume 14, 1993-4.

[Rich-R 2010] Rich, R. (2010). Tuning presets in the motm 650.

[Robertson 1992] Robertson, C. E. (editor) (1992). Musical repercussions of 1492: Encounters in text and performance. Washington, D.C.: Smithsonian Institution Press.

[Sajfert 2011] Sajfert, V., Krstić, S., Popov, D., & Pop, N. (2011). Absorption of sound waves, Seria Fizică (Physics Series), Analele Universităţii de Vest din Timişoara (Annals of the West University of Timisoara), 55, 13–19.

[Sengpiel 2009] Sengpiel, E. (2009). Speed of sound — Temperature matters, not air pressure.

[Shepard-RN 1964] Shepard, R. N. (1964). Circularity in judgements of relative pitch, Journal of the Acoustical Society of America, 36(12), 2346–2353, doi:10.1121/1.1919362.

[Surjodiningrat 1972] Surjodiningrat, W., Sudarjana, P. J., & Susanto, A. (1972). Tone measurements of outstanding Javanese gamelan in Jogjakarta and Surakata, Second Revised Edition. Jogjakarta, Indonesia: Gadjah Mada University Press.

[vanSchaik 2010] Schaik, W. v., Grooten, M., Wernaart, T., & Geld, C. v. d. (2010). High accuracy acoustic relative humidity measurement in duct flow with air, Sensors, 10, 7421–7433, doi:10.3390/s100807421. sensors ISSN 1424-8220 www.mdpi.com/journal/sensors.

[Vey 2010] Vey, G. L. (2012). Optimal control theory: A method for the design of wind instruments, arXiv:1001.3217.

[Wolfe 2003] Wolfe, J., & Smith, J. (2003). Cutoff frequencies and cross fingerings in Baroque, Classical, and Modern flutes, Journal of the Acoustic Society of America, 114(4), 2263–2272, doi:10.1121/1.1612487. Publication 14587623 on PubMed/NCBI (subscription access).

[Yang-WJ 2005] Yang, W., & Umeda, S. (2005). Self-sustained flow oscillations due to flow-surface interaction, Sixteenth International Symposium on Transport Phenomena (ISTP-16), Prague, 2005.

[Yokoyama 2014] Yokoyama, H., Kobayashi, M., Onitsuka, H., Miki, A., & Iida, A. (2014). Direct numerical simulation of flow and acoustic fields around an air-reed instrument with tone holes, 43rd International Congress on Noise Control Engineering (inter.noise 2014), Melbourne, Australia, November 16–19, 2014.

[Yokoyama 2015] Yokoyama, H. (2015). World first prediction of the sound radiating from a recorder — Super-computer simulations explore how an air-reed instrument generates air flow and sound.

[Young-RW 1939] Young, R. W. (1939). Terminology for logarithmic frequency units, Journal of the Acoustical Society of America, 11(1), 134–139, doi:10.1121/1.1916017. ISSN: 0001-4966.

[Zhai 2016] Zhai, S. L., Zhao, X. P., Liu, S., Shen, F. L., & &, L. L. L.; Luo, C. R. (2016). Inverse doppler effects in broadband acoustic metamaterials, Scientific Reports, 6(32388), doi:10.1038/srep32388.

[Zhao 2015] Zhao, X. P., Zhai, S. L., Liu, S., Shen, F. L., Li, L. L., & Luo, C. R. (2015). Inverse doppler effects in flute, arXiv:1510.02868.

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