Laue Indexing with Optimal Transport
arxiv(2024)
摘要
Laue tomography experiments retrieve the positions and orientations of
crystal grains in a polycrystalline samples from diffraction patterns recorded
at multiple viewing angles. The use of a broad wavelength spectrum beam can
greatly reduce the experimental time, but poses a difficult challenge for the
indexing of diffraction peaks in polycrystalline samples; the information about
the wavelength of these Bragg peaks is absent and the diffraction patterns from
multiple grains are superimposed. To date, no algorithms exist capable of
indexing samples with more than about 500 grains efficiently. To address this
need we present a novel method: Laue indexing with Optimal Transport (LaueOT).
We create a probabilistic description of the multi-grain indexing problem and
propose a solution based on Sinkhorn Expectation-Maximization method, which
allows to efficiently find the maximum of the likelihood thanks to the
assignments being calculated using Optimal Transport. This is a non-convex
optimization problem, where the orientations and positions of grains are
optimized simultaneously with grain-to-spot assignments, while robustly
handling the outliers. The selection of initial prototype grains to consider in
the optimization problem are also calculated within the Optimal Transport
framework. LaueOT can rapidly and effectively index up to 1000 grains on a
single large memory GPU within less than 30 minutes. We demonstrate the
performance of LaueOT on simulations with variable numbers of grains, spot
position measurement noise levels, and outlier fractions. The algorithm
recovers the correct number of grains even for high noise levels and up to 70
outliers in our experiments. We compare the results of indexing with LaueOT to
existing algorithms both on synthetic and real neutron diffraction data from
well-characterized samples.
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