Elastic Constant Measurement from Vibrational Mode Frequencies in Resonant Ultrasound Spectroscopy
Barnana Pal

TL;DR
This paper introduces a method to estimate initial elastic constant guesses directly from resonant ultrasound spectra, improving the accuracy of RUS measurements without relying on external experiments.
Contribution
It proposes a novel approach to derive initial elastic constant estimates from RUS spectra using frequency-length relationships, enhancing the RUS fitting process.
Findings
Accurate elastic constants for aluminium, copper, lead, steel, and brass were measured.
The method showed good agreement with literature values.
Initial guesses improved the convergence and accuracy of RUS measurements.
Abstract
Execution of Resonant Ultrasound Spectroscopy (RUS) for accurate measurement of elastic constants lies primarily on a perfect matching in the calculated and measured mode frequencies of free vibration. Calculation of these frequencies require estimated values of the elastic constants of the material under study, and one has to depend on other experiments for these data. The present work proposes and demonstrates an alternative to derive initial guess values of essential parameters for an isotropic and homogeneous material from the acquired RUS spectra itself. Specimen samples are taken in the shape of rectangular parallelepiped having nearly same cross-sectional dimension but with different lengths. For particular compressional (shear) mode corresponding to length l, the frequency fis inversely proportional to l. The slope m of f versus 1/l plot equals to half of the compressional…
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Taxonomy
TopicsUltrasonics and Acoustic Wave Propagation · Non-Destructive Testing Techniques · Ultrasound Imaging and Elastography
