A novel hybrid deterministic-statistical approach for the mid-frequency vibro-acoustic problems

• Published in: Applied Mathematical Modelling Vol. 83; pp. 202 - 219
• Main Authors: Wang, G., Zhang, Y.X., Guo, Z.B., Zhou, Z.G.
• Format: Journal Article
• Language: English
• Published: New York Elsevier Inc 01.07.2020; Elsevier BV
• Subjects: Acoustics; Algorithms; Computer simulation; Finite element analysis; Finite element method; Frequency analysis; Frequency response; Mid-frequency; Numerical methods; Reciprocity; Stable node-based smoothed finite element method; Statistical energy analysis; Subsystems; Vibro-acoustic problems; Stable node-based smoothed finite element method; Vibro-acoustic problems; Numerical methods; Statistical energy analysis; Mid-frequency
• ISSN: 0307-904X; 1088-8691; 0307-904X
• DOI: 10.1016/j.apm.2020.02.026

•A novel hybrid algorithm is proposed for mid-frequency vibro-acoustic analysis.•T-mesh used in mesh discretization facilitates the pre-processing.•Our algorithm possesses higher calculation accuracy and faster convergence rate.•The developed model is insensitive to mesh distortion.•The present method works well for both benchmark and practical engineering cases. It is difficult to predict precisely the frequency response of a complex vibro-acoustic system in mid-frequency region. To overcome this deficiency, a novel hybrid stable node-based smoothed finite element method/statistical energy analysis model is proposed in this work. The whole vibro-acoustic system can be divided into a combination of a structural subsystem with statistical behavior and an acoustic subsystem with deterministic feature. The recently developed stable node-based smoothed finite element method is employed here to simulate the deterministic subsystem, and the statistical energy analysis is utilized to deal with the statistical subsystem. Based on the so-called diffuse field reciprocity relation, these two subsystems can be easily connected and coupled. Due to the introducing of gradient smoothing and compensation operation, our algorithm can significantly reduce the dispersion error compared with the traditional finite element method. Thus, it is expected that the present coupled model can provide ultra-accurate results. Numerical examples, including both benchmark and practical engineering cases, demonstrate that our algorithm works very well in mid-frequency vibro-acoustic analysis.