Page 63 - WINTER2019
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De Forest, L. (1907). Device for Amplifying Feeble Electrical Currents. US Patent No. 841,387, January 15, 1907.
Ding, H. H., McCleary, L. E., and Ward, J. (1973). Computerized Sonar Transducer Analysis and Design Based on Multiport Network Interconnec- tion Techniques. Technical Report NUC-TP-228, Naval Undersea Center, San Diego, CA.
Egerton, H. C. (1921). Telephone Apparatus. US Patent No. 1,365,898, Janu- ary 18, 1921.
Elko, G. W., Kubli, R. A., and Meyer, J. M. (2009). Audio System Based on at Least Second-Order Eigenbeams. US Patent No. 7,587,054, Septem- ber 8, 2009.
Fellgett, P. B. (1973). Ambisonic reproduction of sound. Electronics and Power 19(20), 492-494.
Firestone, F. A. (1942). Flaw Detecting Device and Measuring Instrument. US Patent No. 2,280,226, April 21, 1942.
Fleming, J. A. (1905). Instrument for Converting Alternating Electric Currents into Continuous Currents. US Patent No. 803,684, Novem- ber 7, 1905.
Gray, M. D., Stride, E. P., and Coussios, C.-C. (2019). Snap, crackle, and pop: Theracoustic cavitation. Acoustics Today 15(1), 19-27. https://doi.org/10.1121/AT.2019.15.1.19.
Gutmann, F. (1948). The electret. Reviews of Modern Physics 20(3) 457-472. Holm, D., and Sessler, G. (1983). An integrated silicon-electret-condenser microphone. Proceedings of the 11th International Congress on Acoustics,
Paris, pp. 29-32.
Hueter, T. F. (1972). Twenty years in underwater acoustics: Generation and
reception. The Journal of the Acoustical Society of America 51, 1025-1040.
https://doi.org/10.1121/1.1912922.
Hunt, F. V. (1954). Electroacoustics. Wiley, Cambridge, MA.
Kettering, J. A., and Silverman, R. H. (2017). Clinical and preclinical applications of high-frequency ultrasound. Acoustics Today 13(1), 45-51.
https://doi.org/10.1121/AT.2017.13.1.45.
Konofagou, E. E. (2017). Trespassing the barrier of the brain with ultrasound. Acoustics Today 13(4), 21-26. https://doi.org/10.1121/AT.2017.13.4.21.
Lindenberger, W. S., Poteat, T. L., and West, J. E. (1985). Integrated Elec- troacoustic Transducer with Built-In Bias. US Patent No. 4,524,247, June 18, 1985.
MathWorks (2019). Simscape. Model and Simulate Multidomain Physical Systems. Available at https://www.mathworks.com/products/simscape.html?s_tid=srchtitle. Accessed August 27, 2019.
Matula, T. J., and Chen, H. (2013). Microbubbles as ultrasound contrast agents. Acoustics Today 9(1), 14-20. https://doi.org/10.1121/1.4802075. McLachlan, N. W. (1936). The New Acoustics, Oxford University
Press, London.
Modelica Association (2019). Available at http://modelica.org. Accessed
August 27, 2019.
mh acoustics (2019). Eigenmike® Microphone. Available at
http://mhacoustics.com/products. Accessed August 22, 2019.
Nagel, L. W. (1975). SPICE2: A Computer Program to Simulate Integrated
Circuits. Memorandum No. UCB/ERL M520, Electronics Research Labo-
ratory, University of California, Berkeley, May 5, 1975.
O’Brien, W. D. (2018). Floyd Dunn and his contributions. Acoustics Today
14(1) 35-41. https://doi.org/10.1121/AT.2018.14.1.35.
Olson, H. F. (1947). Elements of Acoustical Engineering, 2nd ed. Van Nos-
trand, New York.
Olson, H. F. (1958). Dynamical Analogies, 2nd ed. Van Nostrand, New York. Olson, H. F., and Massa, F. (1936). Applied Acoustics. Blakiston’s Son &
Co., Philadelphia, PA.
Pridham, E. S., and Jensen, P. L. (1923). Electrodynamic Receiver. US Patent
Rice, C. W. (1929) Loud-speaker. US Patent No. 1,707,570, April 2, 1929. Rice, C. W., and Kellogg, W. W. (1925) Notes on the development of a new type of hornless loud speaker. Transactions of the American Institute of
Electrical Engineers 44, 461-480.
https://doi.org/10.1109/T-AIEE.1925.5061127.
Sherman, C. H., and Butler, J. L. (2007). Transducers and Arrays for Under- water Sound. Springer-Verlag, New York, p. 230.
Siemens, E. W. (1874). Improvement in Magneto-Electric Apparatus. US Patent No. 149,797, April 14, 1874.
Stansfield, D. (1991). Underwater Electroacoustic Transducers. Peninsula, Los Altos Hills, CA
Tarzan, A., Alunno, M., and Bientinesi, P. (2019). Assessment of sound spatial- ization algorithms for sonic rendering with headphones. Journal of New Music Research 48(2), 107-124. https://doi.org/10.1080/09298215.2019.1572766.
Wente, E. C. (1922). The sensitivity and precision of the electrostatic trans- mitter for measuring sound intensities. Physical Review 19, 498-503.
West, J. E. (1988). Modern electret applications — The first 20 years. Proceedings of the 6th International Symposium on Electrets, Oxford, UK, pp. 209-212 https://doi.org/10.1109/ISE.1988.38550.
Wilson, O. B. (1985). An Introduction to the Theory and Design of Sonar Transducers. US Government Printing Office, Washington, DC.
BioSketch
Stephen Thompson is a research professor in the Graduate Program in Acoustics at Pennsylvania State University (University Park). His PhD research was on nonlinear feedback oscillation in woodwind musi- cal instruments. He has previously worked in industrial research and development,
first for a sonar system manufacturer and later for a manufac- turer of miniature OEM audio transducers. His current work includes the analysis, design, and use of acoustic transducers in a wide range of applications. He enjoys the challenges of advising acoustics students through their academic research and watching their careers develop after graduation.
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