Title :
Numerical simulation of ultrasonic wave propagation in anisotropic and attenuative solid materials
Author :
You, Zhongqing ; Lusk, M. ; Ludwig, Reinhold ; Lord, William
Author_Institution :
Dept. of Electr. & Comput. Eng., Iowa State Univ., Ames, IA, USA
Abstract :
The axisymmetric elastodynamic finite element code developed is capable of predicting quantitatively accurate displacement fields for elastic wave propagation in isotropic and transversely isotropic materials. The numerical algorithm incorporates viscous damping by adding a time-dependent tensor to Hooke´s law. Amplitude comparisons are made between the geometric attenuation in the far field and the corresponding finite element predictions to investigate the quality and validity of the code. Through-transmission experimental measurements made with a 1 MHz L-wave transducer attached to an aluminum sample support the code predictions. The algorithm successfully models geometric beam spreading dispersion and energy absorption due to viscous damping. This numerical model is a viable tool for the study of elastic wave propagation in nondestructive testing applications.<>
Keywords :
digital simulation; finite element analysis; numerical methods; ultrasonic materials testing; ultrasonic propagation; 1 MHz; Hooke´s law; L-wave transducer; anisotropic materials; attenuative solid materials; axisymmetric elastodynamic finite element code; displacement fields; elastic wave propagation; energy absorption; geometric attenuation; geometric beam spreading dispersion; nondestructive testing; numerical algorithm; numerical model; numerical simulation; time-dependent tensor; transversely isotropic materials; ultrasonic wave propagation; viscous damping; Aluminum; Anisotropic magnetoresistance; Attenuation; Damping; Elastodynamics; Finite element methods; Numerical simulation; Prediction algorithms; Tensile stress; Transducers;
Journal_Title :
Ultrasonics, Ferroelectrics, and Frequency Control, IEEE Transactions on
