Research on a quantitative method for three-dimensional computed tomography of chemiluminescence

Gongxi Zhou; Fei Li; Kuanliang Wang; Xin Lin; Xilong Yu

doi:10.1364/AO.393225

Research on a quantitative method for three-dimensional computed tomography of chemiluminescence

Gongxi Zhou
, Fei Li^*
, Kuanliang Wang
, Xin Lin
, Xilong Yu

^*Corresponding author for this work

School of Aerospace Engineering

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

9 Citations (Scopus)

Abstract

To develop a more advanced 3D computed tomography of the chemiluminescence method, the first quantitative 3D diagnosis was realized. The nonlinearity coefficient, the nonuniformity coefficient of the camera response, and various optical fiber attenuation coefficients were obtained through correction experiments. The conversion relationship between the number of photons released by the target object per unit time and the camera gray value at a specified solid angle was also calibrated. To verify the quantitative reconstruction equation, 3D reconstructions of a methane-air flat flame and a simulated phantom were performed for comparison. The method can overcome artificial distortions caused by uncorrected reconstruction.

Original language	English
Pages (from-to)	5310-5318
Number of pages	9
Journal	Applied Optics
Volume	59
Issue number	17
DOIs	https://doi.org/10.1364/AO.393225
Publication status	Published - 10 Jun 2020

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title = "Research on a quantitative method for three-dimensional computed tomography of chemiluminescence",

abstract = "To develop a more advanced 3D computed tomography of the chemiluminescence method, the first quantitative 3D diagnosis was realized. The nonlinearity coefficient, the nonuniformity coefficient of the camera response, and various optical fiber attenuation coefficients were obtained through correction experiments. The conversion relationship between the number of photons released by the target object per unit time and the camera gray value at a specified solid angle was also calibrated. To verify the quantitative reconstruction equation, 3D reconstructions of a methane-air flat flame and a simulated phantom were performed for comparison. The method can overcome artificial distortions caused by uncorrected reconstruction.",

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AU - Zhou, Gongxi

AU - Li, Fei

AU - Wang, Kuanliang

AU - Lin, Xin

AU - Yu, Xilong

PY - 2020/6/10

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N2 - To develop a more advanced 3D computed tomography of the chemiluminescence method, the first quantitative 3D diagnosis was realized. The nonlinearity coefficient, the nonuniformity coefficient of the camera response, and various optical fiber attenuation coefficients were obtained through correction experiments. The conversion relationship between the number of photons released by the target object per unit time and the camera gray value at a specified solid angle was also calibrated. To verify the quantitative reconstruction equation, 3D reconstructions of a methane-air flat flame and a simulated phantom were performed for comparison. The method can overcome artificial distortions caused by uncorrected reconstruction.

AB - To develop a more advanced 3D computed tomography of the chemiluminescence method, the first quantitative 3D diagnosis was realized. The nonlinearity coefficient, the nonuniformity coefficient of the camera response, and various optical fiber attenuation coefficients were obtained through correction experiments. The conversion relationship between the number of photons released by the target object per unit time and the camera gray value at a specified solid angle was also calibrated. To verify the quantitative reconstruction equation, 3D reconstructions of a methane-air flat flame and a simulated phantom were performed for comparison. The method can overcome artificial distortions caused by uncorrected reconstruction.

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Research on a quantitative method for three-dimensional computed tomography of chemiluminescence

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