Title :
Frequency domain thickness measurement approach for microscale multilayered structures
Author :
Li, Chen ; Cetinkaya, Cetin
Author_Institution :
Dept. of Mech. & Aeronaut. Eng., Clarkson Univ., Potsdam, NY, USA
Abstract :
A frequency domain thickness measurement approach for multilayered structures consisting of micrometer-scale viscoelastic thin layers is introduced. The technique presented in present work is based on a transfer matrix formulation and pulse/echo boundary conditions. The algorithms are developed from a first-principle-based analysis of linear elastic wave propagation in layered structures. An experimental procedure is introduced for determining the natural frequencies of a multilayer structure consisting of highly attenuative layers. Extraction of layer thicknesses from a set of natural frequencies is also demonstrated. One unique feature of the current technique is that it requires acoustic equipment operating at relatively low frequency. Specific challenges due to strong frequency-dependent attenuation in viscoelastic materials are discussed and addressed.
Keywords :
acoustic measurement; frequency-domain analysis; multilayers; thickness measurement; transfer function matrices; acoustic equipment; acoustic testing; attenuative layers; frequency domain thickness measurement; frequency-dependent attenuation; layered structures; linear elastic wave propagation; micrometer-scale viscoelastic thin layers; microscale multilayered structures; nondestructive testing; pulse/echo boundary conditions; transfer matrix formulation; viscoelastic materials; Attenuation; Biological materials; Boundary conditions; Elasticity; Frequency domain analysis; Nonhomogeneous media; Parameter estimation; Signal to noise ratio; Thickness measurement; Viscosity; Acoustic testing; multilayered structures; multilayers; nondestructive testing; thickness measurement; transfer matrix formulation;
Journal_Title :
Instrumentation and Measurement, IEEE Transactions on
DOI :
10.1109/TIM.2005.860866
