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{{Short description|Technique for modeling the propagation of a wave field}}
The '''angular spectrum method''' is a technique for modeling the propagation of a wave field. This technique involves expanding a complex wave field into a summation of infinite number of [[plane wave]]s. Its mathematical origins lie in the field of [[Fourier optics]]<ref>''Digital Picture Processing'', 2nd edition 1982, Azriel Rosenfeld, Avinash C. Kak, {{ISBN|0-12-597302-0}}, Academic Press, Inc.</ref><ref>''Linear Systems, Fourier Transforms, and Optics'' (Wiley Series in Pure and Applied Optics) Jack D. Gaskill</ref><ref>''Introduction to Fourier Optics'', Joseph W. Goodman.</ref> but it has been applied extensively in the field of [[ultrasound]]. The technique can predict an acoustic pressure field distribution over a plane, based upon knowledge of the pressure field distribution at a parallel plane. Predictions in both the forward and backward propagation directions are possible.<ref>[http://www.egr.msu.edu/~fultras-web/background/asa.php ''Angular Spectrum Approach'', Robert J. McGough]</ref>▼
{{distinguish|Angular spectrum expansion}}
▲The '''angular spectrum method''' is a technique for modeling the propagation of a [[wave field]]. This technique involves expanding a complex wave field into a summation of infinite number of [[plane wave]]s of the same frequency and different directions. Its mathematical origins lie in the field of [[Fourier optics]]<ref>''Digital Picture Processing'', 2nd edition 1982, Azriel Rosenfeld, Avinash C. Kak, {{ISBN|0-12-597302-0}}, Academic Press, Inc.</ref><ref>''Linear Systems, Fourier Transforms, and Optics'' (Wiley Series in Pure and Applied Optics) Jack D. Gaskill</ref><ref>''Introduction to Fourier Optics'', Joseph W. Goodman.</ref> but it has been applied extensively in the field of [[ultrasound]]. The technique can predict an acoustic pressure field distribution over a plane, based upon knowledge of the pressure field distribution at a parallel plane. Predictions in both the forward and backward propagation directions are possible.<ref>[http://www.egr.msu.edu/~fultras-web/background/asa.php ''Angular Spectrum Approach'', Robert J. McGough]</ref>
Modeling the diffraction of a CW (continuous wave), monochromatic (single frequency) field involves the following steps:
# Sampling the complex (real and imaginary) components of a pressure field over a grid of points lying in a cross-sectional plane within the field.
# Taking the 2D-[[Fast Fourier transform|FFT]] (two dimensional [[Fourier transform]]) of the pressure field
# Multiplying each point in the 2D-FFT by a propagation term which accounts for the phase change that each plane wave will undergo on its journey to the prediction plane.
# Taking the 2D-IFFT (two dimensional inverse [[Fourier transform]]) of the resulting data set to yield the field
In addition to predicting the effects of diffraction,<ref>{{cite journal | last1=Waag | first1=R.C. | last2=Campbell | first2=J.A. | last3=Ridder | first3=J. | last4=Mesdag | first4=P.R. | title=Cross-Sectional Measurements and Extrapolations of Ultrasonic Fields | journal=IEEE Transactions on Sonics and Ultrasonics | publisher=Institute of Electrical and Electronics Engineers (IEEE) | volume=32 | issue=1 | year=1985 | issn=0018-9537 | doi=10.1109/t-su.1985.31566 | pages=26–35| bibcode=1985ITSU...32...26W }}</ref><ref>{{cite journal | last1=Stepanishen | first1=Peter R. | last2=Benjamin | first2=Kim C. | title=Forward and backward projection of acoustic fields using FFT methods | journal=The Journal of the Acoustical Society of America | publisher=Acoustical Society of America (ASA) | volume=71 | issue=4 | year=1982 | issn=0001-4966 | doi=10.1121/1.387606 | pages=803–812| bibcode=1982ASAJ...71..803S }}</ref> the model has been extended to apply to non-monochromatic cases (acoustic pulses) and to include the effects of attenuation, refraction, and dispersion. Several researchers have also extended the model to include the nonlinear effects of finite amplitude acoustic propagation (propagation in cases where sound speed is not constant but is dependent upon the instantaneous acoustic pressure).<ref>{{cite journal | last1=Vecchio | first1=Christopher J. | last2=Lewin | first2=Peter A. | title=Finite amplitude acoustic propagation modeling using the extended angular spectrum method | journal=The Journal of the Acoustical Society of America | publisher=Acoustical Society of America (ASA) | volume=95 | issue=5 | year=1994 | issn=0001-4966 | doi=10.1121/1.409849 | pages=2399–2408| bibcode=1994ASAJ...95.2399V }}</ref><ref>{{cite conference |conference=14th Annual International Conference of the IEEE Engineering in Medicine and Biology Society| last1=Vecchio | first1=Chris | last2=Lewin | first2=Peter A. | title=Acoustic propagation modeling using the extended angular spectrum method | publisher=IEEE | year=1992 | isbn=0-7803-0785-2 | doi=10.1109/iembs.1992.5762211
Backward propagation predictions can be used to analyze the surface vibration patterns of acoustic radiators such as [[ultrasonic transducer]]s.<ref>{{cite journal | last1=Schafer | first1=Mark E. | last2=Lewin | first2=Peter A. | title=Transducer characterization using the angular spectrum method | journal=The Journal of the Acoustical Society of America | publisher=Acoustical Society of America (ASA) | volume=85 | issue=5 | year=1989 | issn=0001-4966 | doi=10.1121/1.397869 | pages=2202–2214| bibcode=1989ASAJ...85.2202S | doi-access=free }}</ref> Forward propagation can be used to predict the influence of inhomogeneous, nonlinear media on acoustic transducer performance.<ref>{{cite journal | last1=Vecchio | first1=Christopher J. | last2=Schafer | first2=Mark E. | last3=Lewin | first3=Peter A. | title=Prediction of ultrasonic field propagation through layered media using the extended angular spectrum method | journal=Ultrasound in Medicine & Biology | publisher=Elsevier BV | volume=20 | issue=7 | year=1994 | issn=0301-5629 | doi=10.1016/0301-5629(94)90109-0 | pages=611–622| pmid=7810021 }}</ref>
==See also==
* [[
==References==
{{reflist}}
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