Muography. Группа авторов

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Muography - Группа авторов


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upper Z Subscript 0 n Baseline comma beta Subscript n Baseline right-parenthesis Over q left-parenthesis upper X Subscript m Baseline comma upper Z Subscript 0 n Baseline comma beta Subscript n Baseline right-parenthesis EndFraction q Subscript h Baseline left-parenthesis upper X Subscript m Baseline comma z comma beta Subscript n Baseline right-parenthesis h left-parenthesis upper X 0 minus upper X Subscript m Baseline right-parenthesis EndLayout"/>

      where m and n are the indexes of X and β, respectively.

Schematic illustration of the path length normalization approximation.

      (2.19)italic delta rho Superscript italic a c c Baseline left-parenthesis x comma y comma z right-parenthesis equals StartRoot StartFraction 1 Over upper J minus 1 EndFraction sigma-summation Underscript j equals 1 Overscript upper J Endscripts left-brace rho Subscript j Superscript italic r e c Baseline left-parenthesis x comma y comma z right-parenthesis minus rho Superscript italic r e c Baseline left-parenthesis x comma y comma z right-parenthesis right-brace squared EndRoot

      where j is the index of the trials in the simulation, J is the total number of simulation trials, rho Subscript j Superscript italic r e c Baseline left-parenthesis x comma y comma z right-parenthesis is the reconstructed density image for the j th trial, ρ rec (x, y, z) is the reconstructed density without random numbers, and δρ acc (x, y, z) is the random error caused by the statistical error of the number of muons.

      This section describes an example of performance estimation using the two reconstruction methods.

      The following assumptions and models were used in the simulation. The volcano selected as an example is Omuroyama, located in Ito, Shizuoka Prefecture, Japan. Omuroyama volcano is an inactive scoria cone that is part of the Eastern Izu Monogenetic Volcanic Group, and formed at ca. 4 ka. The basal diameter of the volcano is 800–1000 m, and its relative elevation is ~250 m. Multi‐directional muon tomographic study is ongoing at this volcano for the following reasons: (i) good accessibility for installation of muon detectors in all directions due to well‐maintained roads; (ii) the absence of “shadows” from any other objects in the background; and (iii) the volcano shape is axisymmetric, but non‐axisymmetric structures are expected in the volcano interior (Koyano et al., 1996; Saito et al., 2003).

Schematic illustration of topography around Omuroyama volcano and the location of the muon detectors in the simulation.

      For simplicity, we assumed that the muon detectors have enough capability to reject low‐momentum particles (i.e., the effect of multiple Coulomb scattering is negligible). This assumption is required as the computational needs are too large to calculate the scattering effect. There have been several studies of the contamination of low‐energy particles due to the multiple Coulomb scattering effect around mountains (e.g., Ambrosino et al., 2015; Jourde et al., 2013; Nishiyama et al., 2014b, 2016).


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