A Trial Acoustic Improvement in a Lecture Hall with MPP Sound Absorbers and FDTD Acoustic Simulations

Cingolani, Matteo; Fratoni, Giulia; Barbaresi, Luca; D’Orazio, Dario; Hamilton, Brian; Garai, Massimo

doi:10.3390/app11062445

Cited by 18 publications

(9 citation statements)

References 54 publications

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“…A wide variety of numerical methods are available for timedomain simulations: finite-difference time-domain (FDTD) (Sakamoto, 2007;Kowalczyk and van Walstijn, 2008;Sakamoto et al, 2008;Kowalczyk and van Walstijn, 2011;Hamilton and Bilbao, 2017;Toyoda and Eto, 2019;Cingolani et al, 2021;Toyoda and Sakayoshi, 2021) or finite-volume timedomain (FVTD) methods (Bilbao, 2013;Bilbao et al, 2016), time-domain BEM (TD-BEM) (Hargreaves and Cox, 2008), time-domain FEM (TD-FEM) (Okuzono et al, 2019;Yoshida et al, 2022), time-domain discontinuous Galerkin FEM (DG-FEM) (Simonaho et al, 2012;Wang et al, 2019;Wang and Hornikx, 2020;Pind et al, 2021), time-domain spectral element method (TD-SEM) (Pind et al, 2019), pseudospectral timedomain (PSTD) method (Hornikx et al, 2015;Hornikx et al, 2016), and adaptive rectangular decomposition (ARD) method (Mehra et al, 2012;Morales et al, 2015;Rabisse et al, 2019). They respectively offer several benefits in terms of ease of coding and applicability of complex geometries and so on according to fundamental algorithms of numerical methods.…”

Section: Introductionmentioning

confidence: 99%

High potential of small-room acoustic modeling with 3D time-domain finite element method

Okuzono¹,

Yoshida²

2022

Front. Built Environ.

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Applicability of wave-based acoustics simulation methods in the time domain has increased markedly for performing room-acoustics simulation. They can incorporate sound absorber effects appropriately with a local-reaction frequency-dependent impedance boundary condition and an extended-reaction model. However, their accuracy, efficiency and practicality against a standard frequency-domain solver in 3D room acoustics simulation are still not known well. This paper describes a performance examination of a recently developed time-domain FEM (TD-FEM) for small-room acoustics simulation. This report first describes the significantly higher efficiency of TD-FEM against a frequency-domain FEM (FD-FEM) via acoustics simulation in a small cubic room and a small meeting room, including two porous-type sound absorbers and a resonant-type sound absorber. Those sound absorbers are modeled with local-reaction frequency-dependent impedance boundary conditions and an extended-reaction model. Then, the practicality of time-domain FEM is demonstrated further by simulating the room impulse response of the meeting room under various sound absorber configurations, including the frequency component up to 6 kHz. Results demonstrated the high potential and computational benefit of time-domain FEM as a 3D small room acoustics prediction tool.

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Section: Introductionmentioning

confidence: 99%

High potential of small-room acoustic modeling with 3D time-domain finite element method

Okuzono¹,

Yoshida²

2022

Front. Built Environ.

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“…The feasibility and performance of micro-perforated panels (MPPs) when used as an acoustic treatment in lecture rooms were investigated in this work by Cingolani et al [13]. Three different micro-perforated steel specimens were first designed following existing predictive models and then physically manufactured through 3D additive metal printing.…”

Section: A Trial Acoustic Improvement In a Lecture Hall With Mpp Soun...mentioning

confidence: 99%

Special Issue: Advances in Architectural Acoustics

2022

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“…A parallel approach suitable for acoustic purposes has emerged with success in different applications. These applications encompass but are not limited to sound diffusers [22], [23], absorbing panels [44] and sonic crystal waveguides [45] and SCNB [46].…”

Section: Introductionmentioning

confidence: 99%

Improving Insertion Loss of Sonic Crystal Active Noise Barrier by Reinforcement Learning and Finite Difference Time Domain Simulations

Ramírez-Solana,

Galiana-Nieves,

Redondo

et al. 2024

IEEE Access

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Sonic crystal noise barriers (SCNB) have emerged as a promising solution for mitigating traffic noise pollution. These barriers utilize periodic structures to selectively reflect acoustic waves at specific target frequencies, offering the advantage of being permeable to light and wind. However, their installation and maintenance costs have hindered widespread adoption. In contrast, active noise control (ANC) systems leverage speakers and microphones to generate opposing sound waves that cancel out incoming noise, presenting a potentially cost-effective alternative. The efficacy of ANC, however, hinges on the precision of noise prediction models and control algorithms.Reinforcement Learning (RL) technique, an interdisciplinary area of machine learning, has shown promise in enhancing ANC systems by enabling them to adapt to changing noise conditions and achieve superior noise reduction, particularly in enclosed spaces. Despite these advancements, several challenges remain in applying RL to ANC systems for SCNB. This paper explores these challenges and proposes an RL-based solution for autonomous ANC systems within the context of SCNB, utilizing a Finite Difference Time Domain (FDTD) simulation environment to address low-frequency, moving sources, and outdoor propagation noise scenarios.

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A Trial Acoustic Improvement in a Lecture Hall with MPP Sound Absorbers and FDTD Acoustic Simulations

Cited by 18 publications

References 54 publications

High potential of small-room acoustic modeling with 3D time-domain finite element method

High potential of small-room acoustic modeling with 3D time-domain finite element method

Special Issue: Advances in Architectural Acoustics

Improving Insertion Loss of Sonic Crystal Active Noise Barrier by Reinforcement Learning and Finite Difference Time Domain Simulations

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