A type of acoustic metamaterial plates with grid-stiffened surfaces is proposed, and its mid-to-low frequency sound insulation performance is investigated theoretically, numerically and experimentally in this paper. A key contribution is the introduction of the dynamic effective areal density (DEAD) as a fundamental predictive parameter. Unlike static mass, the DEAD quantifies the effective inertial mass participating in local resonance, directly linking structural dynamics to sound insulation. And the DEAD of the metamaterial plates is derived and analyzed based on the periodicity of the whole structure and the simplified model of the structural unit. This enables the establishment of a theoretical relationship between the design parameters and the sound transmission loss (STL) of the metamaterial plates around the local resonance frequencies, which is demonstrated experimentally. The experimental STL peak frequency agrees well with both the theoretical predictions and the finite element method (FEM) simulations. The frequency range of enhanced sound insulation from theoretical predictions is in close agreement with the band gaps obtained from the simulated band structure. The results would provide guidance and support for the solution design of sound barriers, especially for their sound insulation improvement in vehicle body panels or aircraft cabins.
AndersonPRobertsMWeiC (2024a) Recent advancements in automotive engineering by using evolutionary algorithms and nature-inspired heuristic optimization. Engineering Applications of Artificial Intelligence129: 107642.
2.
AndersonPDaviesTRobertsM, et al. (2024b) Porous liner coated inlet duct: a novel approach to attenuate automotive turbocharger inlet flow-induced sound propagation. Journal of Sound and Vibration568: 118042.
3.
BrillouinL (1953) Wave Propagation in Periodic Structures. Dover Publications.
4.
ChakravertyS (2009) Vibration of Plates. CRC Press.
5.
ChenJSChenYBChenHW, et al. (2016) Bandwidth broadening for transmission loss of acoustic waves using coupled membrane-ring structure. Materials Research Express3: 105801. https://doi.org/10.1088/2053-1591/3/10/105801
6.
ChenXWangYZhangL (2023) An efficient lightweight algorithm for scheduling tasks onto dynamically reconfigurable hardware using graph-oriented simulated annealing. IEEE Transactions on Computer-Aided Design of Integrated Circuits and Systems42(5): 1567–1580.
7.
DaviesTZhangLWangY, et al. (2023) Multi-objective optimization of exponential-cross-section piezoelectric cantilever under tire rotational excitation for self-powered tire pressure monitoring systems. Journal of Sound and Vibration548: 117518.
8.
de Melo FilhoNGRVan BelleLClaeysC, et al. (2019) Dynamic mass based sound transmission loss prediction of vibro-acoustic metamaterial double panels applied to the mass-air-mass resonance. Journal of Sound and Vibration442: 28–44. https://doi.org/10.1016/j.jsv.2018.10.047
9.
FahyF (2001) Foundations of Engineering Acoustics. Elsevier Academic Press.
10.
GonzalezMSinghRWeiC (2025) A new voltage-multiplier-based power converter configuration suitable for renewable energy sources and sustainability applications. IEEE Transactions on Power Electronics40(1): 234–247.
11.
HosseinalibeikiHHosseiniSMRahmatiM (2024) A TSP-based nested clustering approach to solve multi-depot heterogeneous fleet routing problem. Industrial Management Journal16(1): 175–197.
12.
KidnerMRFFullerCRGardnerB (2006) Increase in transmission loss of single panels by addition of mass inclusions to a poro-elastic layer: experimental investigation. Journal of Sound and Vibration294: 466–472. https://doi.org/10.1016/j.jsv.2005.11.022
13.
LiHGonzalezMSinghR (2025) Smooth longitudinal driving strategy with adjustable nonlinear reference model for autonomous vehicles. IEEE Transactions on Intelligent Transportation Systems26(1): 234–247.
14.
LiangXLiangHChuJ, et al. (2024) A composite acoustic black hole for ultra-low-frequency and ultra-broad-band sound wave control. Journal of Vibration and Control30(15-16): 3462–3471. https://doi.org/10.1177/10775463231194702
15.
LuZYuXLauSK, et al. (2020) Membrane-type acoustic metamaterial with eccentric masses for broadband sound isolation. Applied Acoustics157: 107003. https://doi.org/10.1016/j.apacoust.2019.107003
16.
MartinezJLTanakaKSchmidtA (2024a) An analytically derived reference signal to guarantee safety and comfort in adaptive cruise control systems. IEEE Transactions on Intelligent Transportation Systems25(3): 1456–1468.
17.
MartinezJLSchmidtAKumarS (2024b) Simultaneous optimization of fuel and electrical energy consumption in forward looking hybrid electric vehicle. IEEE Transactions on Vehicular Technology73(2): 1456–1468.
18.
MohtavipourSMMollajafariMNaseriA (2019) A guaranteed-comfort and safe adaptive cruise control by considering driver's acceptance level. International Journal of Dynamics and Control7(3): 966–980. https://doi.org/10.1007/s40435-018-0500-5
19.
MohtavipourSMMollajafariMNaseriA (2019) An analytically derived reference signal to guarantee safety and comfort in adaptive cruise control systems. Journal of Intelligent Transportation Systems24(3): 286–298.
20.
MohtavipourSMMollajafariMNaseriA (2020) A novel packet exchanging strategy for preventing HoL-blocking in fat-trees. Cluster Computing23(4): 3025–3043. https://doi.org/10.1007/s10586-019-02940-2
21.
NaifyCJChangCMMcKnightG, et al. (2011) Membrane-type metamaterials: transmission loss of multi-celled arrays. Journal of Applied Physics109: 104902. https://doi.org/10.1063/1.3583656
22.
NazemiSMasih-TehraniMMollajafariM (2022) GA tuned H∞ roll acceleration controller based on series active variable geometry suspension on rough roads. International Journal of Vehicle Performance8(2/3): 166–187. https://doi.org/10.1504/ijvp.2022.122047
23.
NiZ (1989) Mechanics of Vibration. Xi'an Jiaotong University Press. [in Chinese].
OudichMLiYAssouarB, et al. (2010) A sonic band gap based on the locally resonant phononic plates with stubs. New Journal of Physics12: 083049. https://doi.org/10.1088/1367-2630/12/8/083049
26.
PangJ (2015) Noise and Vibration Control of Automotive Body. Beijing: China Machine Press. [in Chinese].
27.
PennecYDjafari-RouhaniBLarabiH, et al. (2008) Low-frequency gaps in a phononic crystal constituted of cylindrical dots deposited on a thin homogeneous plate. Physical Review B78: 104105. https://doi.org/10.1103/physrevb.78.104105
28.
SalehHHosseiniSM (2023) Nonflat surface level pyramid: a high connectivity multidimensional interconnection network. The Journal of Supercomputing79(8): 8921–8942.
29.
SharmaAPatelRChenX (2024) Layerwise formulation of poroelastic composite plate under pre-buckling and thermal shock loading. Composite Structures327: 117639.
30.
VippermanJSLiDAvdeevI, et al. (2003) Investigation of the sound transmission into an advanced grid-stiffened structure. Journal of Vibration and Acoustics125: 257–266. https://doi.org/10.1115/1.1569511
31.
WangSXiaoYGuJ, et al. (2023a) Double-panel metastructure lined with porous material for broadband low-frequency sound insulation. Applied Acoustics207: 109332. https://doi.org/10.1016/j.apacoust.2023.109332
32.
WangYZhangLTanakaK, et al. (2023b) Global-guidance chaotic multi-objective particle swarm optimization method for pneumatic suspension handling and ride quality enhancement on the basis of a thermodynamic model. Mechanical Systems and Signal Processing188: 110315.
33.
XiaoYCaoJWangS, et al. (2021) Sound transmission loss of plate-type metastructures: semi-analytical modeling, elaborate analysis, and experimental validation. Mechanical Systems and Signal Processing153: 107487. https://doi.org/10.1016/j.ymssp.2020.107487
34.
XuWHanHLiQ, et al. (2023) Layerwise formulation of poroelastic composite plate under pre-buckling and thermal shock loading. Composite Structures304: 116343. https://doi.org/10.1016/j.compstruct.2022.116343
35.
YuLMogensOFinnJ (2011) Improvements of the smearing technique for cross-stiffened thin rectangular plates. Journal of Sound and Vibration330: 4274–4286.
36.
ZhangSWuJHuZ (2013a) Low-frequency locally resonant band-gaps in phononic crystal plates with periodic spiral resonators. Journal of Applied Physics113: 163511. https://doi.org/10.1063/1.4803075
37.
ZhangYWenJZhaoH, et al. (2013b) Sound insulation property of membrane-type acoustic metamaterials carrying different masses at adjacent cells. Journal of Applied Physics114: 063515. https://doi.org/10.1063/1.4818435
38.
ZhangJHuBWangS (2023) Review and perspective on acoustic metamaterials: from fundamentals to applications. Applied Physics Letters123: 010502. https://doi.org/10.1063/5.0152099
39.
ZhouXTiongRLKXuY (2024) Sound insulation properties of plate-type acoustic metamaterial structures with different types of resonators. Applied Physics A130: 410. https://doi.org/10.1007/s00339-024-07584-7
