International audienceThis article quantitatively investigates ultrasound propagation in numerical anisotropic porous media with finite-difference simulations in 3D. The propagation media consist of clusters of ellipsoidal scatterers randomly distributed in water, mimicking the anisotropic structure of cancellous bone. Velocities and attenuation coefficients of the ensemble-averaged transmitted wave (also known as the coherent wave) are measured in various configurations. As in real cancellous bone, one or two longitudinal modes emerge, depending on the micro-structure. The results are confronted with two standard theoretical approaches: Biot's theory, usually invoked in porous media, and the Independent Scattering Approximation (ISA), a cl...
Computational studies on the evaluation of bone status in cases of pathologies have gained significa...
International audienceAlthough ultrasound might be useful to assess bone quality, the mechanisms of ...
Cancellous bone is a highly porous material filled with fluid. The mechanical properties of cancello...
International audienceThis article quantitatively investigates ultrasound propagation in numerical a...
The anisotropic pore structure and elasticity of cancellous bone cause wave speeds and attenuation i...
Understanding ultrasound propagation through a porous, heterogeneous and anisotropic structure as tr...
The anisotropic pore structure and elasticity of cancellous bone cause wave speeds and attenuation i...
The theoretical modelling of ultrasonic propagation in cancellous bone is pertinent to the improveme...
The modeling of ultrasonic propagation in cancellous bone is relevant to the study of clinical bone ...
International audienceWhile Biot's theory seems well adapted to model the acoustical waves propagati...
Ultrasonic wave propagation in human cancellous bone is considered using Biot's theory modified by t...
Ultrasonic wave propagation in human cancellous bone is considered. Reflection and transmission coef...
International audienceUltrasonic wave propagation in human cancellous bone is considered using Biot'...
Understanding the propagation of acoustic waves through a liquid-perfused porous solid framework suc...
Understanding the propagation of acoustic waves through a liquid-perfused porous solid framework suc...
Computational studies on the evaluation of bone status in cases of pathologies have gained significa...
International audienceAlthough ultrasound might be useful to assess bone quality, the mechanisms of ...
Cancellous bone is a highly porous material filled with fluid. The mechanical properties of cancello...
International audienceThis article quantitatively investigates ultrasound propagation in numerical a...
The anisotropic pore structure and elasticity of cancellous bone cause wave speeds and attenuation i...
Understanding ultrasound propagation through a porous, heterogeneous and anisotropic structure as tr...
The anisotropic pore structure and elasticity of cancellous bone cause wave speeds and attenuation i...
The theoretical modelling of ultrasonic propagation in cancellous bone is pertinent to the improveme...
The modeling of ultrasonic propagation in cancellous bone is relevant to the study of clinical bone ...
International audienceWhile Biot's theory seems well adapted to model the acoustical waves propagati...
Ultrasonic wave propagation in human cancellous bone is considered using Biot's theory modified by t...
Ultrasonic wave propagation in human cancellous bone is considered. Reflection and transmission coef...
International audienceUltrasonic wave propagation in human cancellous bone is considered using Biot'...
Understanding the propagation of acoustic waves through a liquid-perfused porous solid framework suc...
Understanding the propagation of acoustic waves through a liquid-perfused porous solid framework suc...
Computational studies on the evaluation of bone status in cases of pathologies have gained significa...
International audienceAlthough ultrasound might be useful to assess bone quality, the mechanisms of ...
Cancellous bone is a highly porous material filled with fluid. The mechanical properties of cancello...