Fast Hyperspectral Neutron Tomography

Mohammad Samin Nur Chowdhury; Diyu Yang; Shimin Tang; Singanallur V. Venkatakrishnan; Hassina Z. Bilheux; Gregery T. Buzzard; Charles A. Bouman

doi:10.1109/TCI.2025.3567854

Fast Hyperspectral Neutron Tomography

Mohammad Samin Nur Chowdhury, Diyu Yang, Shimin Tang, Singanallur V. Venkatakrishnan, Hassina Z. Bilheux, Gregery T. Buzzard, Charles A. Bouman

Research output: Contribution to journal › Article › peer-review

Abstract

Hyperspectral neutron computed tomography is a tomographic imaging technique in which thousands of wavelengthspecific neutron radiographs are measured for each tomographic view. In conventional hyperspectral reconstruction, data from each neutron wavelength bin are reconstructed separately, which is extremely time-consuming. These reconstructions often suffer from poor quality due to low signal-to-noise ratios. Consequently, material decomposition based on these reconstructions tends to produce inaccurate estimates of the material spectra and erroneous volumetric material separation. In this paper, we present two novel algorithms for processing hyperspectral neutron data: fast hyperspectral reconstruction and fast material decomposition. Both algorithms rely on a subspace decomposition procedure that transforms hyperspectral views into low-dimensional projection views within an intermediate subspace, where tomographic reconstruction is performed. The use of subspace decomposition dramatically reduces reconstruction time while reducing both noise and reconstruction artifacts. We apply our algorithms to both simulated and measured neutron data and demonstrate that they reduce computation and improve the quality of the results relative to conventional methods.

Original language	English
Pages (from-to)	663-677
Number of pages	15
Journal	IEEE Transactions on Computational Imaging
Volume	11
DOIs	https://doi.org/10.1109/TCI.2025.3567854
State	Published - 2025

Funding

The work of Charles A. Bouman was supported by the Showalter Trust. This work was supported by UT-Battelle, LLC, under Contract DE-AC05-00OR22725 through the U.S. Department of Energy (DOE).This research used resources at the Spallation Neutron Source,a DOE Office of Science User Facility operated by the Oak Ridge National Laboratory. The beam time was allocated to the Spallation Neutrons and Pressure Diffractometer (SNAP) instrument on proposal number IPTS-26894. The U.S. government retains and the publisher, by accepting the article for publication, acknowledges that the U.S. government retains a nonexclusive, paid-up, irrevocable, worldwide license to publish or reproduce the published form of this manuscript, or allow others to do so, for U.S. government purposes. DOE will provide public access to these results of federally sponsored research in accordance with the DOE Public Access Plan (http://energy.gov/downloads/doe-public-access-plan)

Keywords

Clustering
hyperspectral reconstruction
linear attenuation coefficients
material decomposition
neutron Bragg edge imaging
neutron computed tomography
non-negative matrix factorization

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10.1109/TCI.2025.3567854

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title = "Fast Hyperspectral Neutron Tomography",

abstract = "Hyperspectral neutron computed tomography is a tomographic imaging technique in which thousands of wavelengthspecific neutron radiographs are measured for each tomographic view. In conventional hyperspectral reconstruction, data from each neutron wavelength bin are reconstructed separately, which is extremely time-consuming. These reconstructions often suffer from poor quality due to low signal-to-noise ratios. Consequently, material decomposition based on these reconstructions tends to produce inaccurate estimates of the material spectra and erroneous volumetric material separation. In this paper, we present two novel algorithms for processing hyperspectral neutron data: fast hyperspectral reconstruction and fast material decomposition. Both algorithms rely on a subspace decomposition procedure that transforms hyperspectral views into low-dimensional projection views within an intermediate subspace, where tomographic reconstruction is performed. The use of subspace decomposition dramatically reduces reconstruction time while reducing both noise and reconstruction artifacts. We apply our algorithms to both simulated and measured neutron data and demonstrate that they reduce computation and improve the quality of the results relative to conventional methods.",

keywords = "Clustering, hyperspectral reconstruction, linear attenuation coefficients, material decomposition, neutron Bragg edge imaging, neutron computed tomography, non-negative matrix factorization",

author = "Chowdhury, \{Mohammad Samin Nur\} and Diyu Yang and Shimin Tang and Venkatakrishnan, \{Singanallur V.\} and Bilheux, \{Hassina Z.\} and Buzzard, \{Gregery T.\} and Bouman, \{Charles A.\}",

note = "Publisher Copyright: {\textcopyright} 2015 IEEE.",

year = "2025",

doi = "10.1109/TCI.2025.3567854",

language = "English",

volume = "11",

pages = "663--677",

journal = "IEEE Transactions on Computational Imaging",

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T1 - Fast Hyperspectral Neutron Tomography

AU - Chowdhury, Mohammad Samin Nur

AU - Yang, Diyu

AU - Tang, Shimin

AU - Venkatakrishnan, Singanallur V.

AU - Bilheux, Hassina Z.

AU - Buzzard, Gregery T.

AU - Bouman, Charles A.

PY - 2025

Y1 - 2025

N2 - Hyperspectral neutron computed tomography is a tomographic imaging technique in which thousands of wavelengthspecific neutron radiographs are measured for each tomographic view. In conventional hyperspectral reconstruction, data from each neutron wavelength bin are reconstructed separately, which is extremely time-consuming. These reconstructions often suffer from poor quality due to low signal-to-noise ratios. Consequently, material decomposition based on these reconstructions tends to produce inaccurate estimates of the material spectra and erroneous volumetric material separation. In this paper, we present two novel algorithms for processing hyperspectral neutron data: fast hyperspectral reconstruction and fast material decomposition. Both algorithms rely on a subspace decomposition procedure that transforms hyperspectral views into low-dimensional projection views within an intermediate subspace, where tomographic reconstruction is performed. The use of subspace decomposition dramatically reduces reconstruction time while reducing both noise and reconstruction artifacts. We apply our algorithms to both simulated and measured neutron data and demonstrate that they reduce computation and improve the quality of the results relative to conventional methods.

AB - Hyperspectral neutron computed tomography is a tomographic imaging technique in which thousands of wavelengthspecific neutron radiographs are measured for each tomographic view. In conventional hyperspectral reconstruction, data from each neutron wavelength bin are reconstructed separately, which is extremely time-consuming. These reconstructions often suffer from poor quality due to low signal-to-noise ratios. Consequently, material decomposition based on these reconstructions tends to produce inaccurate estimates of the material spectra and erroneous volumetric material separation. In this paper, we present two novel algorithms for processing hyperspectral neutron data: fast hyperspectral reconstruction and fast material decomposition. Both algorithms rely on a subspace decomposition procedure that transforms hyperspectral views into low-dimensional projection views within an intermediate subspace, where tomographic reconstruction is performed. The use of subspace decomposition dramatically reduces reconstruction time while reducing both noise and reconstruction artifacts. We apply our algorithms to both simulated and measured neutron data and demonstrate that they reduce computation and improve the quality of the results relative to conventional methods.

KW - Clustering

KW - hyperspectral reconstruction

KW - linear attenuation coefficients

KW - material decomposition

KW - neutron Bragg edge imaging

KW - neutron computed tomography

KW - non-negative matrix factorization

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SP - 663

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JO - IEEE Transactions on Computational Imaging

JF - IEEE Transactions on Computational Imaging

ER -

Fast Hyperspectral Neutron Tomography

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