Lagrangian finite element treatment of transient vibration/acoustics of biosolids immersed in fluids

Abstract

Superposition principle is used to separate the incident acoustic wave from the scattered and radiated waves in a displacement‐based finite element model. An absorbing boundary condition is applied to the perturbation part of the displacement. Linear constitutive equation allows for inhomogeneous, anisotropic materials, both fluids and solids. Displacement‐based finite elements are used for all materials in the computational volume. Robust performance for materials with limited compressibility is achieved using assumed‐strain nodally integrated simplex elements or incompatible‐mode brick elements. A centered‐difference time‐stepping algorithm is formulated to handle general damping accurately and efficiently. Verification problems (response of empty steel cylinder immersed in water to a step plane wave, and scattering of harmonic plane waves from an elastic sphere) are discussed for assumed‐strain simplex and for voxel‐based brick finite element models. A voxel‐based modeling scheme for complex biological geometries is described, and two illustrative results are presented from the bioacoustics application domain: reception of sound by the human ear and simulation of biosonar in beaked whales. Copyright © 2007 John Wiley & Sons, Ltd.