FDTD Methods for 3-D Room Acoustics Simulation With High-Order Accuracy in Space and Time

Time-domain finite difference (FDTD) methods are popular tools for three-dimensional (3-D) room acoustics modeling, but numerical dispersion is an inherent problem that can place limitations on the usable bandwidth of a given scheme. Compact explicit 27-point schemes and "large-star" schem...

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Veröffentlicht in:	IEEE/ACM transactions on audio, speech, and language processing speech, and language processing, 2017-11, Vol.25 (11), p.2112-2124
Hauptverfasser:	Hamilton, Brian, Bilbao, Stefan
Format:	Artikel
Sprache:	eng
Schlagworte:	Acoustics Artificial reverberation Dispersion Finite difference methods Mathematical model Propagation room acoustics Solid modeling Time-domain analysis time-domain finite difference (FDTD)
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container_title	IEEE/ACM transactions on audio, speech, and language processing
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creator	Hamilton, Brian Bilbao, Stefan
description	Time-domain finite difference (FDTD) methods are popular tools for three-dimensional (3-D) room acoustics modeling, but numerical dispersion is an inherent problem that can place limitations on the usable bandwidth of a given scheme. Compact explicit 27-point schemes and "large-star" schemes with high-order spatial differences offer improvements to the simplest scheme, but are ultimately limited by their second-order accuracy in time. In this paper, we use modified equation methods to derive FDTD schemes with high orders of accuracy in both space and time, resulting in significant improvements in numerical dispersion as compared to the aforementioned schemes. In comparison to such schemes, the high-order accurate schemes presented in this paper use significantly less memory and fewer operations when low error tolerances in numerical phase velocities are critical, leading to higher usable bandwidths for auralization purposes. Simulation results are also presented, demonstrating improved approximations to modal frequencies of a shoe-box room and free-space propagation of a bandlimited pulse.
doi_str_mv	10.1109/TASLP.2017.2744799
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Compact explicit 27-point schemes and "large-star" schemes with high-order spatial differences offer improvements to the simplest scheme, but are ultimately limited by their second-order accuracy in time. In this paper, we use modified equation methods to derive FDTD schemes with high orders of accuracy in both space and time, resulting in significant improvements in numerical dispersion as compared to the aforementioned schemes. In comparison to such schemes, the high-order accurate schemes presented in this paper use significantly less memory and fewer operations when low error tolerances in numerical phase velocities are critical, leading to higher usable bandwidths for auralization purposes. 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Compact explicit 27-point schemes and "large-star" schemes with high-order spatial differences offer improvements to the simplest scheme, but are ultimately limited by their second-order accuracy in time. In this paper, we use modified equation methods to derive FDTD schemes with high orders of accuracy in both space and time, resulting in significant improvements in numerical dispersion as compared to the aforementioned schemes. In comparison to such schemes, the high-order accurate schemes presented in this paper use significantly less memory and fewer operations when low error tolerances in numerical phase velocities are critical, leading to higher usable bandwidths for auralization purposes. Simulation results are also presented, demonstrating improved approximations to modal frequencies of a shoe-box room and free-space propagation of a bandlimited pulse.</abstract><pub>IEEE</pub><doi>10.1109/TASLP.2017.2744799</doi><tpages>13</tpages><oa>free_for_read</oa></addata></record>
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subjects	Acoustics Artificial reverberation Dispersion Finite difference methods Mathematical model Propagation room acoustics Solid modeling Time-domain analysis time-domain finite difference (FDTD)
title	FDTD Methods for 3-D Room Acoustics Simulation With High-Order Accuracy in Space and Time
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