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Research article
First published January 2002

Application of the Boundary Element Method to Prediction of Highway Noise Barrier Performance

Sanghoon Suh, Luc Mongeau, and J. Stuart BoltonView all authors and affiliations
Volume 1792, Issue 1
https://doi.org/10.3141/1792-09

Abstract

The boundary element method has proven to be an important tool for the computational solution of many engineering problems. A commercial boundary element code was applied to traffic noise barrier analysis. First, it is shown that boundary element models may be used to quantify the accuracy of existing, approximate barrier models, for example, diffraction-based models. Diffraction-based models have been widely applied in noise control engineering applications owing to their relative ease of use. Recently, it was suggested that multipath diffraction components should be summed on a phase-coherent basis instead of on an energy basis. Here the accuracy of a phase-coherent diffraction model has been verified against the boundary element solution, showing limitations of the diffraction model. Second, the boundary element method was used to calculate a new barrier performance metric. In the past, the insertion loss has been considered the most important measure of noise barrier performance. However, insertion loss is normally defined at a particular receiver point in the shadow zone, and its value may vary significantly from point to point. The propagating sound power calculated on a recovery plane in the barrier shadow zone provides a more effective performance measure than does insertion loss when comparing the performance of different barrier designs.

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References

1. Maekawa Z. Noise Reduction by Screens. Applied Acoustics, Vol. 1, 1968, pp. 157–173.
Crossref
Google Scholar
2. Kurze U. J., and Anderson G. S. Sound Attenuation by Barriers. Applied Acoustics, Vol. 4, 1971, pp. 35–53.
Crossref
Google Scholar
3. Lam Y. W. Using Maekawa’s Chart to Calculate Finite Length Barrier Insertion Loss. Applied Acoustics, Vol. 42, 1994, pp. 29–40.
Crossref
Google Scholar
4. Fyfe K. R. A Study of 2D and 3D Barrier Insertion Loss Using Improved Diffraction-Based Methods. Applied Acoustics, Vol. 53, 1998, pp. 49–75.
Crossref
Google Scholar
5. Pierce A. D. Diffraction of Sound Around Corners and over Wide Barriers. Journal of the Acoustical Society of America, Vol. 55, 1974, pp. 941–955.
Crossref
Google Scholar
6. Hayek S. Mathematical Modeling of Absorbent Highway Noise Barriers. Applied Acoustics, Vol. 31, 1990, pp. 77–100.
Crossref
Google Scholar
7. Hothersall D. C., Chandler-Wilde S. N., and Hajmirzae M. N. Efficiency ofSingle Noise Barriers. Journal of Sound and Vibration, Vol. 146, 1991, pp. 303–322.
Crossref
Google Scholar
8. SYSNOISE, Version 5.5. LMS International, Leuven, Belgium, 2000.
Google Scholar
9. MSC Patran, Version 9.0. MSC Software Corporation, Santa Ana, Calif., 1999.
Google Scholar
10. Hothersall D. C., Crombie D. H., and Chandler-Wilde S. N. The Performance of T-Profile and Associated Noise Barriers, Applied Acoustics, Vol. 32, 1991, pp. 269–287.
Crossref
Google Scholar

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Published In

Volume 1792, Issue 1
Pages: 65 - 74
Article first published: January 2002
Issue published: January 2002

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© 2002 National Academy of Sciences.
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Authors

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Sanghoon Suh
School of Mechanical Engineering, Purdue University, 1077, Ray W. Herrick Laboratories, West Lafayette, IN 47907-1077
View all articles by this author
Luc Mongeau
School of Mechanical Engineering, Purdue University, 1077, Ray W. Herrick Laboratories, West Lafayette, IN 47907-1077
View all articles by this author
J. Stuart Bolton
School of Mechanical Engineering, Purdue University, 1077, Ray W. Herrick Laboratories, West Lafayette, IN 47907-1077
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