A Robust Extrapolation Method for Curtailed Aperture Reconstruction in Acoustic Imaging
Acoustic Imaging based sound localization using microphone
array is a challenging task in digital-signal processing.
Discrete Fourier transform (DFT) based near-field acoustical holography
(NAH) is an important acoustical technique for sound source
localization and provide an efficient solution to the ill-posed problem.
However, in practice, due to the usage of small curtailed aperture
and its consequence of significant spectral leakage, the DFT could
not reconstruct the active-region-of-sound (AROS) effectively, especially
near the edges of aperture. In this paper, we emphasize the
fundamental problems of DFT-based NAH, provide a solution to
spectral leakage effect by the extrapolation based on linear predictive
coding and 2D Tukey windowing. This approach has been tested to
localize the single and multi-point sound sources. We observe that
incorporating extrapolation technique increases the spatial resolution,
localization accuracy and reduces spectral leakage when small curtail
aperture with a lower number of sensors accounts.
[1] S. Rick, L. Ines, B. R. N, and N. Henk, "Truncated aperture extrapolation
for fourier-based near-field acoustic holography by means of borderpadding,"
Journal of the Acoustical Society of America, vol. 125(6), pp.
3844-3854, 2009.
[2] E. G. Williams and J. D. Maynard, "Holographic imaging without the
wavelength resoultion limit," Phys. Rev. Lett., vol. 45, pp. 554-557,
1980.
[3] J. D. Maynard, E. G. Williams, and Y. Lee, "Nearfield acoustic holography:
I. theory of generalized holography and the development of nah,"
J. Acoust. Soc. Am., vol. 78, pp. 1395-1413, 1985.
[4] E. G. Williams, Fourier Acoustics: Sound Radiation and Nearfield
Acoustical Holography. Academic, London, 1999.
[5] S. F. Wu, "Methods for reconstructing acoustic quantities based on
acoustic pressure measurements," J. Acoust. Soc. Am., vol. 12, no. 5,
pp. 2680-2697, Nov. 2008.
[6] J. Hald, "Basic theory and properties of statistically optimized near-field
acoustical holography," Journal of the Acoustical Society of America,
vol. 125(4), pp. 2105-2120, 2009.
[7] S. Kenji and U. Hiroshi, "Data extrapolation method for boundary
element method based near-field acoustical holography," Journal of the
Acoustical Society of America, vol. 115(2), pp. 785-796, 2004.
[8] Z. Wang and S. F. Wu, "Helmholtz equation-least-squares method for
reconstructing the acoustic pressure field," J. Acoust. Soc. Am., vol. 102,
pp. 2020-2032, 1997.
[9] E. G. Williams, H. H. Brian, and C. H. Peter, "Fast fourier transform and
singular value decomposition formulations for patch nearfield acoustical
holography," Journal of the Acoustical Society of America, vol. 114(3),
pp. 1322-1333, 2003.
[10] D. J. Chappell and P. J. Harris, "A burton-miller inverse boundary
element method for nearfield acoustic holography," Journal of the
Acoustical Society of America, vol. 126(1), pp. 149-157, 2009.
[11] R. Steiner and J. Hald, "Near-field acoustical holography without the
errors and limitations casued by the use of spatial dft," Int. J. Acoust.
Vib., vol. 6, pp. 83-89, 2001.
[12] S. R. Woolston, "Development of methods to propagate energy density
and predict farfield directivity using nearfield acoustic holography,"
Master of Science thesis, Brigham Young University, pp. 1-155, 2009.
[13] M. C. Harris and J. D. Blotter, "Obtaining the complex pressure field at
the hologram surface for use in near-field acoustical holography when
pressure and in-plane velocities are measured," Journal of the Acoustical
Society of America, vol. 119(2), pp. 888-816, 2006.
[14] Y. H. Kim, "Acoustic holography(chapter 26)," Springer Handbook of
Acoustics, vol. 10.1007/978-0-387-30425-0, pp. 1077-1099, 2007.
[15] A. J. Berkhout, "A holographic approach to acoustic control," J.Audio
Eng.Soc., vol. 36, pp. 977-995, 1988.
[16] E. G. Williams and J. D. Maynard, "Numerical evluation of rayliegh
integral for planar acoustic radiators using the fft," Journal of the
Acoustical Society of America, vol. 72(6), pp. 2020-2030, 1982.
[17] K. Saijyou and S. Yoshikawa, "Reduction methods of the reconstruction
error for large-scale implementation of near-field acoustical holography,"
H. Acoust. Soc. Am., vol. 110, no. 4, pp. 2007-2023, 2001.
[18] R. Bremananth, A. W. H. Khong, and A. Chitra, "Localizing acoustic
touch impacts using zip-stuffing in complex k-space domain," World
Academy of Science, Engineering and Technology Journal, vol. 60, pp.
1389-1395, 2011.
[19] B. Liu, R. Bremananth, and A. W. H. Khong, "A wavenumber-fitting
extrapolation method for fft-based near-field acoistic holography using
microphone array," ICASSP2011, Prague, pp. 145-148, 2011.
[1] S. Rick, L. Ines, B. R. N, and N. Henk, "Truncated aperture extrapolation
for fourier-based near-field acoustic holography by means of borderpadding,"
Journal of the Acoustical Society of America, vol. 125(6), pp.
3844-3854, 2009.
[2] E. G. Williams and J. D. Maynard, "Holographic imaging without the
wavelength resoultion limit," Phys. Rev. Lett., vol. 45, pp. 554-557,
1980.
[3] J. D. Maynard, E. G. Williams, and Y. Lee, "Nearfield acoustic holography:
I. theory of generalized holography and the development of nah,"
J. Acoust. Soc. Am., vol. 78, pp. 1395-1413, 1985.
[4] E. G. Williams, Fourier Acoustics: Sound Radiation and Nearfield
Acoustical Holography. Academic, London, 1999.
[5] S. F. Wu, "Methods for reconstructing acoustic quantities based on
acoustic pressure measurements," J. Acoust. Soc. Am., vol. 12, no. 5,
pp. 2680-2697, Nov. 2008.
[6] J. Hald, "Basic theory and properties of statistically optimized near-field
acoustical holography," Journal of the Acoustical Society of America,
vol. 125(4), pp. 2105-2120, 2009.
[7] S. Kenji and U. Hiroshi, "Data extrapolation method for boundary
element method based near-field acoustical holography," Journal of the
Acoustical Society of America, vol. 115(2), pp. 785-796, 2004.
[8] Z. Wang and S. F. Wu, "Helmholtz equation-least-squares method for
reconstructing the acoustic pressure field," J. Acoust. Soc. Am., vol. 102,
pp. 2020-2032, 1997.
[9] E. G. Williams, H. H. Brian, and C. H. Peter, "Fast fourier transform and
singular value decomposition formulations for patch nearfield acoustical
holography," Journal of the Acoustical Society of America, vol. 114(3),
pp. 1322-1333, 2003.
[10] D. J. Chappell and P. J. Harris, "A burton-miller inverse boundary
element method for nearfield acoustic holography," Journal of the
Acoustical Society of America, vol. 126(1), pp. 149-157, 2009.
[11] R. Steiner and J. Hald, "Near-field acoustical holography without the
errors and limitations casued by the use of spatial dft," Int. J. Acoust.
Vib., vol. 6, pp. 83-89, 2001.
[12] S. R. Woolston, "Development of methods to propagate energy density
and predict farfield directivity using nearfield acoustic holography,"
Master of Science thesis, Brigham Young University, pp. 1-155, 2009.
[13] M. C. Harris and J. D. Blotter, "Obtaining the complex pressure field at
the hologram surface for use in near-field acoustical holography when
pressure and in-plane velocities are measured," Journal of the Acoustical
Society of America, vol. 119(2), pp. 888-816, 2006.
[14] Y. H. Kim, "Acoustic holography(chapter 26)," Springer Handbook of
Acoustics, vol. 10.1007/978-0-387-30425-0, pp. 1077-1099, 2007.
[15] A. J. Berkhout, "A holographic approach to acoustic control," J.Audio
Eng.Soc., vol. 36, pp. 977-995, 1988.
[16] E. G. Williams and J. D. Maynard, "Numerical evluation of rayliegh
integral for planar acoustic radiators using the fft," Journal of the
Acoustical Society of America, vol. 72(6), pp. 2020-2030, 1982.
[17] K. Saijyou and S. Yoshikawa, "Reduction methods of the reconstruction
error for large-scale implementation of near-field acoustical holography,"
H. Acoust. Soc. Am., vol. 110, no. 4, pp. 2007-2023, 2001.
[18] R. Bremananth, A. W. H. Khong, and A. Chitra, "Localizing acoustic
touch impacts using zip-stuffing in complex k-space domain," World
Academy of Science, Engineering and Technology Journal, vol. 60, pp.
1389-1395, 2011.
[19] B. Liu, R. Bremananth, and A. W. H. Khong, "A wavenumber-fitting
extrapolation method for fft-based near-field acoistic holography using
microphone array," ICASSP2011, Prague, pp. 145-148, 2011.
@article{"International Journal of Information, Control and Computer Sciences:54525", author = "R. Bremananth", title = "A Robust Extrapolation Method for Curtailed Aperture Reconstruction in Acoustic Imaging", abstract = "Acoustic Imaging based sound localization using microphone
array is a challenging task in digital-signal processing.
Discrete Fourier transform (DFT) based near-field acoustical holography
(NAH) is an important acoustical technique for sound source
localization and provide an efficient solution to the ill-posed problem.
However, in practice, due to the usage of small curtailed aperture
and its consequence of significant spectral leakage, the DFT could
not reconstruct the active-region-of-sound (AROS) effectively, especially
near the edges of aperture. In this paper, we emphasize the
fundamental problems of DFT-based NAH, provide a solution to
spectral leakage effect by the extrapolation based on linear predictive
coding and 2D Tukey windowing. This approach has been tested to
localize the single and multi-point sound sources. We observe that
incorporating extrapolation technique increases the spatial resolution,
localization accuracy and reduces spectral leakage when small curtail
aperture with a lower number of sensors accounts.", keywords = "Acoustic Imaging, Discrete Fourier Transform (DFT),
k-space wavenumber, Near-Field Acoustical Holography (NAH),
Source Localization, Spectral Leakage.", volume = "6", number = "8", pages = "976-16", }
