[1]KHAN J, KETZEL M, KAKOSIMOS K, et al.Road traffic air and noise pollution exposure assessment: a review of tools and techniques[J].Science of the Total Environment, 2018,634: 661-676.
[2]OKUZONO T, YOSHIDA T, SAKAGAMI K, et al.An explicit time-domain finite element method for room acoustics simulations: comparison of the performance with implicit methods[J].Applied Acoustics, 2016,104: 76-84.
[3]LI W, CHAI Y B, LEI M, et al.Analysis of coupled structural-acoustic problems based on the smoothed finite element method (S-FEM)[J].Engineering Analysis with Boundary Elements, 2014,42: 84-91.
[4]LIU Y J.On the BEM for acoustic wave problems[J].Engineering Analysis with Boundary Elements, 2019,107: 53-62.
[5]FISCHER M, GAUGER U, GAUL L.A multipole Galerkin boundary element method for acoustics[J].Engineering Analysis with Boundary Elements, 2004,28(2): 155-162.
[6]BEWES O G, THOMPSON D J, JONES C J C, et al.Calculation of noise from railway bridges and viaducts: experimental validation of a rapid calculation model[J].Journal of Sound and Vibration, 2006,293(3/4/5): 933-943.
[7]KITAGAWA T, THOMPSON D J.Comparison of wheel/rail noise radiation on Japanese railways using the TWINS model and microphone array measurements[J].Journal of Sound and Vibration, 2006,293(3/4/5): 496-509.
[8]HSIAO G C, LIU F S, SUN J G, et al.A coupled BEM and FEM for the interior transmission problem in acoustics[J].Journal of Computational and Applied Mathematics, 2011,235(17): 5213-5221.
[9]GAO R X, ZHANG Y H, KENNEDY D.A hybrid boundary element-statistical energy analysis for the mid-frequency vibration of vibro-acoustic systems[J].Computers & Structures, 2018,203: 34-42.
[10]HE Z C, LI G Y, ZHONG Z H, et al.An ES-FEM for accurate analysis of 3D mid-frequency acoustics using tetrahedron mesh[J].Computers & Structures, 2012,106/107: 125-134.
[11]CHOPARD B, DROZ M.Cellular automata modeling of physical systems[M].Cambridge: Cambridge University Press, 1998.
[12]LEAMY M J.Application of cellular automata modeling to seismic elastodynamics[J].International Journal of Solids and Structures, 2008,45(17): 4835-4849.
[13]NISHAWALA V V, OSTOJA-STARZEWSKI M, LEAMY M J, et al.Simulation of elastic wave propagation using cellular automata and peridynamics, and comparison with experiments[J].Wave Motion, 2016,60: 73-83.
[14]KRUTAR R A, NUMRICH S K, SQUIER R K.Computation of acoustic field behavior using a lattice gas model[C]//OCEANS 91: Ocean Technologies and Opportunities in the Pacific for the 90’s.Honololu: IEEE, 1991.
[15]NUMRICH S K, KRUTAR R A, SQUIER R K.Computation of acoustic fields on a massively parallel processor using lattice gas methods[J].Computational Acoustics, 1993,1: 81-92.
[16]SUDO Y, SPARROW V W.A new lattice gas model for 1D sound propagation[J].Journal of Computational Acoustics, 1993,1(4): 423-454.
[17]SUDO Y, SPARROW V W.Sound propagation simulations using lattice gas methods[J].American Institute of Aeronautics and Astronautics Journal, 1995,33(9): 1582-1589.
[18]KOMATSUZAKI T, SATO H, IWATA Y, et al.Simulation of acoustic wave propagation using cellular automata[J].Transactions of the Japan Society for Computational Engineering and Science, 1999,1: 135-140.
[19]CHEN M C, WEN Q Q, ZHU Q, et al.Simulation of corrosion process for concrete filled steel tubular columns with the cellular automata method[J].Engineering Failure Analysis, 2017,82: 298-307.
[20]KOMATSUZAKI T, IWATA Y, MORISHITA S.Modelling of incident sound wave propagation around sound barriers using cellular automata[C]//International Conference on Cellular Automata.Berlin: Springer, 2012. |