Nuclear Technology and Radiation Protection (Jan 2024)

An approach based on gamma-ray transmission technique and artificial neural network for accurately measuring the thickness of various materials

  • Trang Le Thi Ngoc,
  • Linh Nguyen Thi Truc,
  • Thanh Tran Thien,
  • Tam Hoang Duc,
  • Chuong Huynh Dinh

DOI
https://doi.org/10.2298/NTRP2402098T
Journal volume & issue
Vol. 39, no. 2
pp. 98 – 110

Abstract

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This paper presents an approach based on the gamma-ray transmission technique and artificial neural network for accurately measuring the thickness of various materials in flat sheet form. The gamma-ray transmission system comprises a NaI(Tl) scintillation detector coupled with a 137Cs radioactive source. The artificial neural network model predicts the sample thickness through three input features: mass density, linear attenuation coefficient, and ln(R) - where R represents the ratio of areas under the 662 keV peak in spectra acquired from measurements with and without the sample. The artificial neural network model was trained using simulation data generated by MCNP6 code, facilitating the creation of comprehensive datasets covering diverse material types and thickness variations at a low cost. Hyperparameters of the artificial neural network model were defined by several optimization methods, such as hyperband-bayesian, tree-structured Parzen estimator, and random search, to establish an optimal artificial neural network architecture. Subsequently, the optimal artificial neural network model was deployed to predict the thickness of graphite, aluminum, copper, steel, and polymethyl methacrylate sheets, using input data obtained from the experiments. The results showed a good agreement between predicted and reference thicknesses, with a maximum relative deviation of 1.94 % and an average relative deviation of 0.52%.

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