Multiband infrared inversion for low-concentration methane monitoring in a confined dust-polluted atmosphere

Wenzheng Wang; Yanming Wang; Wujun Song; Xueqin Li

doi:10.1364/AO.56.002548

Multiband infrared inversion for low-concentration methane monitoring in a confined dust-polluted atmosphere

Wenzheng Wang, Yanming Wang, Wujun Song, and Xueqin Li

Applied Optics
Vol. 56,
Issue 9,
pp. 2548-2555
(2017)
•https://doi.org/10.1364/AO.56.002548

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Wenzheng Wang, Yanming Wang, Wujun Song, and Xueqin Li, "Multiband infrared inversion for low-concentration methane monitoring in a confined dust-polluted atmosphere," Appl. Opt. 56, 2548-2555 (2017)

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Related Topics
Table of Contents Category
- Atmospheric and Oceanic Optics
Optics & Photonics Topics
?

The topics in this list come from the OSA Optics and Photonics Topics applied to this article.
Previously assigned OCIS codes
- Air pollution monitoring (010.1120)
- Atmospheric transmittance (010.1320)
- Infrared (040.3060)
- Inverse problems (100.3190)
- Absorption (300.1030)

About this Article
History
- Original Manuscript: January 6, 2017
- Revised Manuscript: February 22, 2017
- Manuscript Accepted: February 23, 2017
- Published: March 17, 2017

Accessible

Open Access

Abstract

A multiband infrared diagnostic (MBID) method for methane emission monitoring in limited underground environments was presented considering the strong optical background of gas/solid attenuation. Based on spatial distribution of aerosols and complex refractive index of dust particles, forward calculations were carried out with/without methane to obtain the spectral transmittance through the participating atmosphere in a mine roadway. Considering the concurrent attenuation and absorption behavior of dust and gases, four infrared wavebands were selected to retrieve the methane concentration combined with a stochastic particle swarm optimization (SPSO) algorithm. Inversion results prove that the presented MBID method is robust and effective in identifying methane at concentrations of 0.1% or even lower with inversed relative error within 10%. Further analyses illustrate that the four selected wavebands are indispensable, and the MBID method is still valid with transmission signal disturbance in a conventional dust-polluted atmosphere under mechanized mining condition. However, the effective detection distance should be limited within 50 m to ensure inversed relative error less than 5% at 1% methane concentration.

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References

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M. Ajrash, J. Zanganeh, and B. Moghtaderi, “Effects of ignition energy on fire and explosion characteristics of dilute hybrid fuel in ventilation air methane,” J. Loss Prev. Process Ind. 40, 207–216 (2016).
[Crossref]
J. Kurnia, A. Sasmito, and A. Mujumdar, “CFD simulation of methane dispersion and innovative methane management in underground mining faces,” Appl. Math. Model. 38, 3467–3484 (2014).
[Crossref]
H. Chen, H. Qi, and Q. Feng, “Characteristics of direct causes and human factors in major gas explosion accidents in Chinese coal mines: case study spanning the years 1980–2010,” J. Loss Prev. Process Ind. 26, 38–44 (2013).
[Crossref]
Q. Zhang and Q. Ma, “Dynamic pressure induced by a methane-air explosion in a coal mine,” Proc. Saf. Environ. Prot. 93, 233–239 (2015).
[Crossref]
W. Z. Wang, Y. M. Wang, G. Q. Shi, and D. M. Wang, “Numerical study on infrared optical property of diffuse coal particles in mine fully mechanized working combined with CFD method,” Math. Probl. Eng. 2015, 501401 (2015).
[Crossref]
S. Jiang, Z. Wu, and H. Shao, Safety Monitoring and Control (China University of Mining and Technology, 2013).
F. Liu, Y. Zhang, Y. Yu, J. Xu, J. Sun, and G. Lu, “Enhanced sensing performance of catalytic combustion methane sensor by using Pd nanorod/γ-Al2O3,” Sens. Actuatator B 160, 1091–1097 (2011).
[Crossref]
H. Lin, Z. Liang, E. Li, M. Yang, and B. Zhai, “Analysis and design of an improved light interference methane sensor,” in Proceedings of IEEE International Conference on Control and Automation (ICCA) (IEEE, 2014), pp. 504–509.
W. Z. Wang, Y. M. Wang, and G. Q. Shi, “Waveband selection within 400–4000 cm−1 of optical identification of airborne dust in coal mine tunneling face,” Appl. Opt. 55, 2951–2959 (2016).
[Crossref]
S. Su, H. W. Chen, P. Teakle, and S. Xue, “Characteristics of coalmine ventilation air flows,” J. Environ. Manage. 86, 44–62 (2008).
[Crossref]
B. Zhang, C. Bai, G. Xiu, Q. Liu, and G. Gong, “Explosion and flame characteristics of methane/air mixtures in a large-scale vessel,” Process Saf. Prog. 33, 362–368 (2014).
[Crossref]
Z. Li, Z. Lu, Q. Wu, and A. Zhang, “Numerical simulation study of goaf methane drainage and spontaneous combustion coupling,” J. Chin. Univ. Mining Technol. 17, 0503–0507 (2007).
[Crossref]
H. Jin, Y. Chen, Z. Ge, S. Liu, C. Ren, and L. Guo, “Hydrogen production by Zhundong coal gasification in supercritical water,” Int. J. Hydrogen Energy 40, 16096–16103 (2015).
[Crossref]
W. Z. Wang, Y. M. Wang, and G. Q. Shi, “Experimental investigation on the infrared refraction and extinction properties of rock dust in tunneling face of coal mine,” Appl. Opt. 54, 10532–10540 (2015).
[Crossref]
X. Huang, X. Chen, Y. Shuai, Y. Yuan, T. Zhang, B. Li, and H. Tan, “Heat transfer analysis of solar-thermal dissociation of NiFe2O4 by coupling MCRTM and FVM method,” Energy Convers. Manage. 106, 676–686 (2015).
[Crossref]
L. Rouleau, J. Deü, A. Legay, and F. Le Lay, “Application of Kramers–Kronig relations to time-temperature superposition for viscoelastic materials,” Mech. Mater. 65, 66–75 (2013).
[Crossref]
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H. Tan, L. Liu, H. Yi, J. Zhao, H. Qi, and J. Tan, “Recent progress in computational thermal radiative transfer,” Chinese Sci. Bull. 54, 4135–4147 (2009).
[Crossref]
C. A. Wang, L. X. Ma, J. Y. Tan, and L. H. Liu, “Study of radiative transfer in 1D densely packed bed layer containing absorbing-scattering spherical particles,” Int. J. Heat Mass Transfer 102, 669–678 (2016).
[Crossref]
W. Z. Wang, Y. M. Wang, and G. Q. Shi, “Forward research on transmission characteristics of near-surface particulate-matter-polluted atmosphere in mining area combined with CFD method,” Opt. Express 23, A1010–A1023 (2015).
[Crossref]
H. Wei, X. Chen, R. Rao, Y. Wang, and P. Yang, “A moderate-spectral-resolution transmittance model based on fitting the line-by-line calculation,” Opt. Express 15, 8360–8370 (2007).
[Crossref]
Y. Zhang, H. L. Yi, and H. P. Tan, “Lattice Boltzmann method for one-dimensional vector radiative transfer,” Opt. Express 24, 2027–2046 (2016).
[Crossref]
Y. Sun, J. Ma, and B. Li, “Spectral collocation method for convective-radiative transfer of a moving rod with variable thermal conductivity,” Int. J. Therm. Sci. 90, 187–196 (2015).
[Crossref]
F. Q. Wang, Y. Shuai, H. P. Tan, and C. L. Yu, “Thermal performance analysis of porous media receiver with concentrated solar irradiation,” Int. J. Heat Mass Transfer 62, 247–254 (2013).
[Crossref]
M. Kim, J. Cho, and S. Baek, “Radiative heat transfer between two concentric spheres separated by a two-phase mixture of non-gray gas and particles using the modified discrete-ordinates method,” J. Quant. Spectrosc. Radiat. Transfer 109, 1607–1621 (2008).
[Crossref]
Z. H. Ruan, Y. Yuan, and X. X. Zhang, “Determination of optical properties and thickness of optical thin film using stochastic particle swarm optimization,” Sol. Energy 127, 147–158 (2016).
[Crossref]
X. H. Chang and Y. M. Wang, “Coal fire depth-profile reconstruction from ground penetrating radar data,” Inf. Int. Interdiscip. J. 15, 4647–4652 (2012).
Y. Yuan, H. L. Yi, Y. Shuai, F. Q. Wang, and H. P. Tan, “Inverse problem for particle size distributions of atmospheric aerosols using stochastic particle swarm optimization,” J. Quant. Spectrosc. Radiat. Transfer 111, 2106–2114 (2010).
[Crossref]
Y. M. Wang, W. Z. Wang, Z. L. Shao, D. M. Wang, and G. Q. Shi, “Innovative prediction model of carbon monoxide emission from deep mined coal oxidation,” Bulg. Chem. Commun. 46, 887–895 (2014).
K. Gao, Z. G. Liu, J. Liu, Y. Kang, and K. F. Huang, “Numerical simulation of the influence of working face air leakage on gob gas flow laws,” Safe. Coal Mines 43, 8–11 (2012).
M. Krasnyansky, “Prevention and suppression of explosions in gas-air and dust-air mixtures using powder aerosol-inhibitor,” J. Loss Prev. Process Ind. 19, 729–735 (2006).
[Crossref]

2016 (5)

M. Ajrash, J. Zanganeh, and B. Moghtaderi, “Effects of ignition energy on fire and explosion characteristics of dilute hybrid fuel in ventilation air methane,” J. Loss Prev. Process Ind. 40, 207–216 (2016).
[Crossref]

Z. H. Ruan, Y. Yuan, and X. X. Zhang, “Determination of optical properties and thickness of optical thin film using stochastic particle swarm optimization,” Sol. Energy 127, 147–158 (2016).
[Crossref]

C. A. Wang, L. X. Ma, J. Y. Tan, and L. H. Liu, “Study of radiative transfer in 1D densely packed bed layer containing absorbing-scattering spherical particles,” Int. J. Heat Mass Transfer 102, 669–678 (2016).
[Crossref]

Y. Zhang, H. L. Yi, and H. P. Tan, “Lattice Boltzmann method for one-dimensional vector radiative transfer,” Opt. Express 24, 2027–2046 (2016).
[Crossref]

W. Z. Wang, Y. M. Wang, and G. Q. Shi, “Waveband selection within 400–4000 cm−1 of optical identification of airborne dust in coal mine tunneling face,” Appl. Opt. 55, 2951–2959 (2016).
[Crossref]

2015 (7)

W. Z. Wang, Y. M. Wang, and G. Q. Shi, “Forward research on transmission characteristics of near-surface particulate-matter-polluted atmosphere in mining area combined with CFD method,” Opt. Express 23, A1010–A1023 (2015).
[Crossref]

W. Z. Wang, Y. M. Wang, and G. Q. Shi, “Experimental investigation on the infrared refraction and extinction properties of rock dust in tunneling face of coal mine,” Appl. Opt. 54, 10532–10540 (2015).
[Crossref]

X. Huang, X. Chen, Y. Shuai, Y. Yuan, T. Zhang, B. Li, and H. Tan, “Heat transfer analysis of solar-thermal dissociation of NiFe2O4 by coupling MCRTM and FVM method,” Energy Convers. Manage. 106, 676–686 (2015).
[Crossref]

H. Jin, Y. Chen, Z. Ge, S. Liu, C. Ren, and L. Guo, “Hydrogen production by Zhundong coal gasification in supercritical water,” Int. J. Hydrogen Energy 40, 16096–16103 (2015).
[Crossref]

Y. Sun, J. Ma, and B. Li, “Spectral collocation method for convective-radiative transfer of a moving rod with variable thermal conductivity,” Int. J. Therm. Sci. 90, 187–196 (2015).
[Crossref]

Q. Zhang and Q. Ma, “Dynamic pressure induced by a methane-air explosion in a coal mine,” Proc. Saf. Environ. Prot. 93, 233–239 (2015).
[Crossref]

W. Z. Wang, Y. M. Wang, G. Q. Shi, and D. M. Wang, “Numerical study on infrared optical property of diffuse coal particles in mine fully mechanized working combined with CFD method,” Math. Probl. Eng. 2015, 501401 (2015).
[Crossref]

2014 (3)

J. Kurnia, A. Sasmito, and A. Mujumdar, “CFD simulation of methane dispersion and innovative methane management in underground mining faces,” Appl. Math. Model. 38, 3467–3484 (2014).
[Crossref]

B. Zhang, C. Bai, G. Xiu, Q. Liu, and G. Gong, “Explosion and flame characteristics of methane/air mixtures in a large-scale vessel,” Process Saf. Prog. 33, 362–368 (2014).
[Crossref]

Y. M. Wang, W. Z. Wang, Z. L. Shao, D. M. Wang, and G. Q. Shi, “Innovative prediction model of carbon monoxide emission from deep mined coal oxidation,” Bulg. Chem. Commun. 46, 887–895 (2014).

2013 (3)

F. Q. Wang, Y. Shuai, H. P. Tan, and C. L. Yu, “Thermal performance analysis of porous media receiver with concentrated solar irradiation,” Int. J. Heat Mass Transfer 62, 247–254 (2013).
[Crossref]

H. Chen, H. Qi, and Q. Feng, “Characteristics of direct causes and human factors in major gas explosion accidents in Chinese coal mines: case study spanning the years 1980–2010,” J. Loss Prev. Process Ind. 26, 38–44 (2013).
[Crossref]

L. Rouleau, J. Deü, A. Legay, and F. Le Lay, “Application of Kramers–Kronig relations to time-temperature superposition for viscoelastic materials,” Mech. Mater. 65, 66–75 (2013).
[Crossref]

2012 (2)

K. Gao, Z. G. Liu, J. Liu, Y. Kang, and K. F. Huang, “Numerical simulation of the influence of working face air leakage on gob gas flow laws,” Safe. Coal Mines 43, 8–11 (2012).

X. H. Chang and Y. M. Wang, “Coal fire depth-profile reconstruction from ground penetrating radar data,” Inf. Int. Interdiscip. J. 15, 4647–4652 (2012).

2011 (1)

F. Liu, Y. Zhang, Y. Yu, J. Xu, J. Sun, and G. Lu, “Enhanced sensing performance of catalytic combustion methane sensor by using Pd nanorod/γ-Al2O3,” Sens. Actuatator B 160, 1091–1097 (2011).
[Crossref]

2010 (1)

Y. Yuan, H. L. Yi, Y. Shuai, F. Q. Wang, and H. P. Tan, “Inverse problem for particle size distributions of atmospheric aerosols using stochastic particle swarm optimization,” J. Quant. Spectrosc. Radiat. Transfer 111, 2106–2114 (2010).
[Crossref]

2009 (1)

H. Tan, L. Liu, H. Yi, J. Zhao, H. Qi, and J. Tan, “Recent progress in computational thermal radiative transfer,” Chinese Sci. Bull. 54, 4135–4147 (2009).
[Crossref]

2008 (2)

M. Kim, J. Cho, and S. Baek, “Radiative heat transfer between two concentric spheres separated by a two-phase mixture of non-gray gas and particles using the modified discrete-ordinates method,” J. Quant. Spectrosc. Radiat. Transfer 109, 1607–1621 (2008).
[Crossref]

S. Su, H. W. Chen, P. Teakle, and S. Xue, “Characteristics of coalmine ventilation air flows,” J. Environ. Manage. 86, 44–62 (2008).
[Crossref]

2007 (2)

Z. Li, Z. Lu, Q. Wu, and A. Zhang, “Numerical simulation study of goaf methane drainage and spontaneous combustion coupling,” J. Chin. Univ. Mining Technol. 17, 0503–0507 (2007).
[Crossref]

H. Wei, X. Chen, R. Rao, Y. Wang, and P. Yang, “A moderate-spectral-resolution transmittance model based on fitting the line-by-line calculation,” Opt. Express 15, 8360–8370 (2007).
[Crossref]

2006 (1)

M. Krasnyansky, “Prevention and suppression of explosions in gas-air and dust-air mixtures using powder aerosol-inhibitor,” J. Loss Prev. Process Ind. 19, 729–735 (2006).
[Crossref]

Ajrash, M.

Baek, S.

Bai, C.

B. Zhang, C. Bai, G. Xiu, Q. Liu, and G. Gong, “Explosion and flame characteristics of methane/air mixtures in a large-scale vessel,” Process Saf. Prog. 33, 362–368 (2014).
[Crossref]

Chang, X. H.

X. H. Chang and Y. M. Wang, “Coal fire depth-profile reconstruction from ground penetrating radar data,” Inf. Int. Interdiscip. J. 15, 4647–4652 (2012).

Chen, H.

Chen, H. W.

S. Su, H. W. Chen, P. Teakle, and S. Xue, “Characteristics of coalmine ventilation air flows,” J. Environ. Manage. 86, 44–62 (2008).
[Crossref]

Chen, X.

H. Wei, X. Chen, R. Rao, Y. Wang, and P. Yang, “A moderate-spectral-resolution transmittance model based on fitting the line-by-line calculation,” Opt. Express 15, 8360–8370 (2007).
[Crossref]

Chen, Y.

H. Jin, Y. Chen, Z. Ge, S. Liu, C. Ren, and L. Guo, “Hydrogen production by Zhundong coal gasification in supercritical water,” Int. J. Hydrogen Energy 40, 16096–16103 (2015).
[Crossref]

Cho, J.

Deü, J.

L. Rouleau, J. Deü, A. Legay, and F. Le Lay, “Application of Kramers–Kronig relations to time-temperature superposition for viscoelastic materials,” Mech. Mater. 65, 66–75 (2013).
[Crossref]

Feng, Q.

Gao, K.

K. Gao, Z. G. Liu, J. Liu, Y. Kang, and K. F. Huang, “Numerical simulation of the influence of working face air leakage on gob gas flow laws,” Safe. Coal Mines 43, 8–11 (2012).

Ge, Z.

H. Jin, Y. Chen, Z. Ge, S. Liu, C. Ren, and L. Guo, “Hydrogen production by Zhundong coal gasification in supercritical water,” Int. J. Hydrogen Energy 40, 16096–16103 (2015).
[Crossref]

Gong, G.

B. Zhang, C. Bai, G. Xiu, Q. Liu, and G. Gong, “Explosion and flame characteristics of methane/air mixtures in a large-scale vessel,” Process Saf. Prog. 33, 362–368 (2014).
[Crossref]

Guo, L.

H. Jin, Y. Chen, Z. Ge, S. Liu, C. Ren, and L. Guo, “Hydrogen production by Zhundong coal gasification in supercritical water,” Int. J. Hydrogen Energy 40, 16096–16103 (2015).
[Crossref]

Huang, K. F.

K. Gao, Z. G. Liu, J. Liu, Y. Kang, and K. F. Huang, “Numerical simulation of the influence of working face air leakage on gob gas flow laws,” Safe. Coal Mines 43, 8–11 (2012).

Huang, X.

Jiang, S.

S. Jiang, Z. Wu, and H. Shao, Safety Monitoring and Control (China University of Mining and Technology, 2013).

Jin, H.

H. Jin, Y. Chen, Z. Ge, S. Liu, C. Ren, and L. Guo, “Hydrogen production by Zhundong coal gasification in supercritical water,” Int. J. Hydrogen Energy 40, 16096–16103 (2015).
[Crossref]

Kang, Y.

K. Gao, Z. G. Liu, J. Liu, Y. Kang, and K. F. Huang, “Numerical simulation of the influence of working face air leakage on gob gas flow laws,” Safe. Coal Mines 43, 8–11 (2012).

Kim, M.

Krasnyansky, M.

M. Krasnyansky, “Prevention and suppression of explosions in gas-air and dust-air mixtures using powder aerosol-inhibitor,” J. Loss Prev. Process Ind. 19, 729–735 (2006).
[Crossref]

Kurnia, J.

J. Kurnia, A. Sasmito, and A. Mujumdar, “CFD simulation of methane dispersion and innovative methane management in underground mining faces,” Appl. Math. Model. 38, 3467–3484 (2014).
[Crossref]

Le Lay, F.

L. Rouleau, J. Deü, A. Legay, and F. Le Lay, “Application of Kramers–Kronig relations to time-temperature superposition for viscoelastic materials,” Mech. Mater. 65, 66–75 (2013).
[Crossref]

Legay, A.

L. Rouleau, J. Deü, A. Legay, and F. Le Lay, “Application of Kramers–Kronig relations to time-temperature superposition for viscoelastic materials,” Mech. Mater. 65, 66–75 (2013).
[Crossref]

Li, B.

Y. Sun, J. Ma, and B. Li, “Spectral collocation method for convective-radiative transfer of a moving rod with variable thermal conductivity,” Int. J. Therm. Sci. 90, 187–196 (2015).
[Crossref]

Li, E.

H. Lin, Z. Liang, E. Li, M. Yang, and B. Zhai, “Analysis and design of an improved light interference methane sensor,” in Proceedings of IEEE International Conference on Control and Automation (ICCA) (IEEE, 2014), pp. 504–509.

Li, Z.

Z. Li, Z. Lu, Q. Wu, and A. Zhang, “Numerical simulation study of goaf methane drainage and spontaneous combustion coupling,” J. Chin. Univ. Mining Technol. 17, 0503–0507 (2007).
[Crossref]

Liang, Z.

Lin, H.

Liu, F.

Liu, J.

K. Gao, Z. G. Liu, J. Liu, Y. Kang, and K. F. Huang, “Numerical simulation of the influence of working face air leakage on gob gas flow laws,” Safe. Coal Mines 43, 8–11 (2012).

Liu, L.

H. Tan, L. Liu, H. Yi, J. Zhao, H. Qi, and J. Tan, “Recent progress in computational thermal radiative transfer,” Chinese Sci. Bull. 54, 4135–4147 (2009).
[Crossref]

Liu, L. H.

Liu, Q.

B. Zhang, C. Bai, G. Xiu, Q. Liu, and G. Gong, “Explosion and flame characteristics of methane/air mixtures in a large-scale vessel,” Process Saf. Prog. 33, 362–368 (2014).
[Crossref]

Liu, S.

H. Jin, Y. Chen, Z. Ge, S. Liu, C. Ren, and L. Guo, “Hydrogen production by Zhundong coal gasification in supercritical water,” Int. J. Hydrogen Energy 40, 16096–16103 (2015).
[Crossref]

Liu, Z. G.

K. Gao, Z. G. Liu, J. Liu, Y. Kang, and K. F. Huang, “Numerical simulation of the influence of working face air leakage on gob gas flow laws,” Safe. Coal Mines 43, 8–11 (2012).

Lu, G.

Lu, Z.

Z. Li, Z. Lu, Q. Wu, and A. Zhang, “Numerical simulation study of goaf methane drainage and spontaneous combustion coupling,” J. Chin. Univ. Mining Technol. 17, 0503–0507 (2007).
[Crossref]

Ma, J.

Y. Sun, J. Ma, and B. Li, “Spectral collocation method for convective-radiative transfer of a moving rod with variable thermal conductivity,” Int. J. Therm. Sci. 90, 187–196 (2015).
[Crossref]

Ma, L. X.

Ma, Q.

Q. Zhang and Q. Ma, “Dynamic pressure induced by a methane-air explosion in a coal mine,” Proc. Saf. Environ. Prot. 93, 233–239 (2015).
[Crossref]

Moghtaderi, B.

Mujumdar, A.

J. Kurnia, A. Sasmito, and A. Mujumdar, “CFD simulation of methane dispersion and innovative methane management in underground mining faces,” Appl. Math. Model. 38, 3467–3484 (2014).
[Crossref]

Qi, H.

H. Tan, L. Liu, H. Yi, J. Zhao, H. Qi, and J. Tan, “Recent progress in computational thermal radiative transfer,” Chinese Sci. Bull. 54, 4135–4147 (2009).
[Crossref]

Rao, R.

H. Wei, X. Chen, R. Rao, Y. Wang, and P. Yang, “A moderate-spectral-resolution transmittance model based on fitting the line-by-line calculation,” Opt. Express 15, 8360–8370 (2007).
[Crossref]

Ren, C.

H. Jin, Y. Chen, Z. Ge, S. Liu, C. Ren, and L. Guo, “Hydrogen production by Zhundong coal gasification in supercritical water,” Int. J. Hydrogen Energy 40, 16096–16103 (2015).
[Crossref]

Rouleau, L.

L. Rouleau, J. Deü, A. Legay, and F. Le Lay, “Application of Kramers–Kronig relations to time-temperature superposition for viscoelastic materials,” Mech. Mater. 65, 66–75 (2013).
[Crossref]

Ruan, Z. H.

Sasmito, A.

J. Kurnia, A. Sasmito, and A. Mujumdar, “CFD simulation of methane dispersion and innovative methane management in underground mining faces,” Appl. Math. Model. 38, 3467–3484 (2014).
[Crossref]

Shao, H.

S. Jiang, Z. Wu, and H. Shao, Safety Monitoring and Control (China University of Mining and Technology, 2013).

Shao, Z. L.

Y. M. Wang, W. Z. Wang, Z. L. Shao, D. M. Wang, and G. Q. Shi, “Innovative prediction model of carbon monoxide emission from deep mined coal oxidation,” Bulg. Chem. Commun. 46, 887–895 (2014).

Shi, G. Q.

Y. M. Wang, W. Z. Wang, Z. L. Shao, D. M. Wang, and G. Q. Shi, “Innovative prediction model of carbon monoxide emission from deep mined coal oxidation,” Bulg. Chem. Commun. 46, 887–895 (2014).

Shuai, Y.

Su, S.

S. Su, H. W. Chen, P. Teakle, and S. Xue, “Characteristics of coalmine ventilation air flows,” J. Environ. Manage. 86, 44–62 (2008).
[Crossref]

Sun, J.

Sun, Y.

Y. Sun, J. Ma, and B. Li, “Spectral collocation method for convective-radiative transfer of a moving rod with variable thermal conductivity,” Int. J. Therm. Sci. 90, 187–196 (2015).
[Crossref]

Tan, H.

H. Tan, L. Liu, H. Yi, J. Zhao, H. Qi, and J. Tan, “Recent progress in computational thermal radiative transfer,” Chinese Sci. Bull. 54, 4135–4147 (2009).
[Crossref]

Tan, H. P.

Y. Zhang, H. L. Yi, and H. P. Tan, “Lattice Boltzmann method for one-dimensional vector radiative transfer,” Opt. Express 24, 2027–2046 (2016).
[Crossref]

Tan, J.

H. Tan, L. Liu, H. Yi, J. Zhao, H. Qi, and J. Tan, “Recent progress in computational thermal radiative transfer,” Chinese Sci. Bull. 54, 4135–4147 (2009).
[Crossref]

Tan, J. Y.

Teakle, P.

S. Su, H. W. Chen, P. Teakle, and S. Xue, “Characteristics of coalmine ventilation air flows,” J. Environ. Manage. 86, 44–62 (2008).
[Crossref]

Wang, C. A.

Wang, D. M.

Y. M. Wang, W. Z. Wang, Z. L. Shao, D. M. Wang, and G. Q. Shi, “Innovative prediction model of carbon monoxide emission from deep mined coal oxidation,” Bulg. Chem. Commun. 46, 887–895 (2014).

Wang, F. Q.

Wang, W. Z.

Y. M. Wang, W. Z. Wang, Z. L. Shao, D. M. Wang, and G. Q. Shi, “Innovative prediction model of carbon monoxide emission from deep mined coal oxidation,” Bulg. Chem. Commun. 46, 887–895 (2014).

Wang, Y.

H. Wei, X. Chen, R. Rao, Y. Wang, and P. Yang, “A moderate-spectral-resolution transmittance model based on fitting the line-by-line calculation,” Opt. Express 15, 8360–8370 (2007).
[Crossref]

Wang, Y. M.

Y. M. Wang, W. Z. Wang, Z. L. Shao, D. M. Wang, and G. Q. Shi, “Innovative prediction model of carbon monoxide emission from deep mined coal oxidation,” Bulg. Chem. Commun. 46, 887–895 (2014).

X. H. Chang and Y. M. Wang, “Coal fire depth-profile reconstruction from ground penetrating radar data,” Inf. Int. Interdiscip. J. 15, 4647–4652 (2012).

Wei, H.

H. Wei, X. Chen, R. Rao, Y. Wang, and P. Yang, “A moderate-spectral-resolution transmittance model based on fitting the line-by-line calculation,” Opt. Express 15, 8360–8370 (2007).
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[Crossref]

Wu, Z.

S. Jiang, Z. Wu, and H. Shao, Safety Monitoring and Control (China University of Mining and Technology, 2013).

Xiu, G.

B. Zhang, C. Bai, G. Xiu, Q. Liu, and G. Gong, “Explosion and flame characteristics of methane/air mixtures in a large-scale vessel,” Process Saf. Prog. 33, 362–368 (2014).
[Crossref]

Xu, J.

Xue, S.

S. Su, H. W. Chen, P. Teakle, and S. Xue, “Characteristics of coalmine ventilation air flows,” J. Environ. Manage. 86, 44–62 (2008).
[Crossref]

Yang, M.

Yang, P.

H. Wei, X. Chen, R. Rao, Y. Wang, and P. Yang, “A moderate-spectral-resolution transmittance model based on fitting the line-by-line calculation,” Opt. Express 15, 8360–8370 (2007).
[Crossref]

Yi, H.

H. Tan, L. Liu, H. Yi, J. Zhao, H. Qi, and J. Tan, “Recent progress in computational thermal radiative transfer,” Chinese Sci. Bull. 54, 4135–4147 (2009).
[Crossref]

Yi, H. L.

Y. Zhang, H. L. Yi, and H. P. Tan, “Lattice Boltzmann method for one-dimensional vector radiative transfer,” Opt. Express 24, 2027–2046 (2016).
[Crossref]

Yu, C. L.

Yu, Y.

Yuan, Y.

Zanganeh, J.

Zhai, B.

Zhang, A.

Z. Li, Z. Lu, Q. Wu, and A. Zhang, “Numerical simulation study of goaf methane drainage and spontaneous combustion coupling,” J. Chin. Univ. Mining Technol. 17, 0503–0507 (2007).
[Crossref]

Zhang, B.

B. Zhang, C. Bai, G. Xiu, Q. Liu, and G. Gong, “Explosion and flame characteristics of methane/air mixtures in a large-scale vessel,” Process Saf. Prog. 33, 362–368 (2014).
[Crossref]

Zhang, Q.

Q. Zhang and Q. Ma, “Dynamic pressure induced by a methane-air explosion in a coal mine,” Proc. Saf. Environ. Prot. 93, 233–239 (2015).
[Crossref]

Zhang, T.

Zhang, X. X.

Zhang, Y.

Y. Zhang, H. L. Yi, and H. P. Tan, “Lattice Boltzmann method for one-dimensional vector radiative transfer,” Opt. Express 24, 2027–2046 (2016).
[Crossref]

Zhao, J.

H. Tan, L. Liu, H. Yi, J. Zhao, H. Qi, and J. Tan, “Recent progress in computational thermal radiative transfer,” Chinese Sci. Bull. 54, 4135–4147 (2009).
[Crossref]

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[Crossref]

Appl. Opt. (2)

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Y. M. Wang, W. Z. Wang, Z. L. Shao, D. M. Wang, and G. Q. Shi, “Innovative prediction model of carbon monoxide emission from deep mined coal oxidation,” Bulg. Chem. Commun. 46, 887–895 (2014).

Chinese Sci. Bull. (1)

H. Tan, L. Liu, H. Yi, J. Zhao, H. Qi, and J. Tan, “Recent progress in computational thermal radiative transfer,” Chinese Sci. Bull. 54, 4135–4147 (2009).
[Crossref]

Energy Convers. Manage. (1)

Inf. Int. Interdiscip. J. (1)

X. H. Chang and Y. M. Wang, “Coal fire depth-profile reconstruction from ground penetrating radar data,” Inf. Int. Interdiscip. J. 15, 4647–4652 (2012).

Int. J. Heat Mass Transfer (2)

Int. J. Hydrogen Energy (1)

H. Jin, Y. Chen, Z. Ge, S. Liu, C. Ren, and L. Guo, “Hydrogen production by Zhundong coal gasification in supercritical water,” Int. J. Hydrogen Energy 40, 16096–16103 (2015).
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Y. Sun, J. Ma, and B. Li, “Spectral collocation method for convective-radiative transfer of a moving rod with variable thermal conductivity,” Int. J. Therm. Sci. 90, 187–196 (2015).
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J. Chin. Univ. Mining Technol. (1)

Z. Li, Z. Lu, Q. Wu, and A. Zhang, “Numerical simulation study of goaf methane drainage and spontaneous combustion coupling,” J. Chin. Univ. Mining Technol. 17, 0503–0507 (2007).
[Crossref]

J. Environ. Manage. (1)

S. Su, H. W. Chen, P. Teakle, and S. Xue, “Characteristics of coalmine ventilation air flows,” J. Environ. Manage. 86, 44–62 (2008).
[Crossref]

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H. Wei, X. Chen, R. Rao, Y. Wang, and P. Yang, “A moderate-spectral-resolution transmittance model based on fitting the line-by-line calculation,” Opt. Express 15, 8360–8370 (2007).
[Crossref]

Y. Zhang, H. L. Yi, and H. P. Tan, “Lattice Boltzmann method for one-dimensional vector radiative transfer,” Opt. Express 24, 2027–2046 (2016).
[Crossref]

Proc. Saf. Environ. Prot. (1)

Q. Zhang and Q. Ma, “Dynamic pressure induced by a methane-air explosion in a coal mine,” Proc. Saf. Environ. Prot. 93, 233–239 (2015).
[Crossref]

Process Saf. Prog. (1)

B. Zhang, C. Bai, G. Xiu, Q. Liu, and G. Gong, “Explosion and flame characteristics of methane/air mixtures in a large-scale vessel,” Process Saf. Prog. 33, 362–368 (2014).
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Sens. Actuatator B (1)

Sol. Energy (1)

Other (4)

S. Jiang, Z. Wu, and H. Shao, Safety Monitoring and Control (China University of Mining and Technology, 2013).

https://www.bruker.com/products/infrared-near-infrared-and-raman-spectroscopy/ft-ir-research-spectrometers/vertex-series/vertex-8080v/overview.html .

http://aacc.cumt.edu.cn/model/TwoGradePage/NewsEquipment.aspx?id=46287&openid=154&tab=two .

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Fig. 1. Schematic of the underground mining area and sampling points.

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Fig. 2. SEM image of coal dust particles: (a)

scale = 20 μm

and (b)

scale = 50 μm

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Fig. 3. Spectral transmittance of coal dust particles from FT-IR test.

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Fig. 4. Complex refractive index of coal particles.

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Fig. 5. Spectral transmittance of confined atmosphere with/without methane gas.

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Fig. 6. Selection of spectral bands for inverse calculation.

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Fig. 7. Convergence process of the inversed calculation.

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Fig. 8. Coal dust concentration distribution in forward calculation and its area integral.

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Fig. 9. Variation range of inversed gas concentration.

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Fig. 10. Relative error of inversed result with different spectral band combination.

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Fig. 11. Influence of (a) dust concentration and (b) detection distance on inversed result.

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Tables (6)

Table 1. Spatial Distribution of Coal Dust

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Table 2. Conventional Gas Composition in Underground Atmosphere

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Table 3. Inversed Result of Methane Concentration and Coal Dust Parameters

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Table 4. Comparison of Accuracy between MBID Method and Catalytic Combustion Method

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Table 5. Four Types of Combination of Spectral Bands

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Table 6. Inverse Calculation Performance When Different Transmission Signal Errors Added

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Equations (2)

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f (c, ρ, α, β) = \frac{1}{N} \sqrt{\sum_{i = 1}^{N} {(\frac{τ - \bar{τ}}{τ})}^{2}},

δ = \frac{| c - \bar{c} |}{c} \times 100,

		Particle Size Distribution (%)
Distance (m)	Dust Concentration ( $mg / m^{3}$ )	$\sim 2 μm$	2–5 μm	5–10 μm	$> 10 μm$
0.1	281.16	17.56	23.44	28.37	30.63
2.0	265.32	21.85	23.34	25.94	28.87
4.0	228.09	24.74	22.65	21.15	31.46
6.0	215.64	20.76	23.67	28.8	26.77
8.0	177.91	29.55	21.13	25.48	23.84
10.0	178.59	35.20	26.97	28.19	9.64

Typical condition	$N_{2}$ (%)	$O_{2}$ (%)	${CO}_{2}$ (%)	$H_{2} O$ (%)	${CH}_{4}$ (%)	Others (%)
Fresh air	76.653	20.599	0.040	2.705	0	0.003
Contaminated air	75.399	19.992	0.039	3.567	1	0.003

Gas Concentration (%)
True Value	Inversed Value	Relative Error (%)	Inversed Coal Dust Concentration ( $mg / m^{3}$ )
0.01	0.0116	16.00	212.41
0.05	0.0487	2.60	202.05
0.1	0.0923	7.70	211.02
0.2	0.1864	6.80	208.99
0.4	0.3858	3.55	206.34
0.6	0.5824	2.93	209.71
0.8	0.7880	1.50	211.91
1.0	0.9907	0.93	210.82
2.0	2.0205	1.03	208.05
3.0	3.0301	1.00	208.32
4.0	4.0200	0.50	208.40
5.0	4.9827	0.35	206.71

MBID Method			Catalytic Combustion Method
	Absolute Error (%)
True Gas Concentration (%)	Positive	Negative	True Gas Concentration (%)	Absolute Error (%)
0.01	0.002 ${CH}_{4}$	$- 0.003 {CH}_{4}$	0–1	$\pm 0.10 {CH}_{4}$
0.1	0.004 ${CH}_{4}$	$- 0.004 {CH}_{4}$
0.2	0.005 ${CH}_{4}$	$- 0.004 {CH}_{4}$
0.6	0.004 ${CH}_{4}$	$- 0.006 {CH}_{4}$
1.0	0.004 ${CH}_{4}$	$- 0.004 {CH}_{4}$	1–2	$\pm 0.20 {CH}_{4}$
3.0	0.002 ${CH}_{4}$	$- 0.003 {CH}_{4}$	2–4	$\pm 0.30 {CH}_{4}$
5.0	0.017 ${CH}_{4}$	$- 0.012 {CH}_{4}$	4–40	$\pm 0.80 {CH}_{4}$

Type	Number of Selected Bands	Wave Number ( ${cm}^{- 1}$ )	Comment
(a)	4	$1275 \pm 10$	Influenced by both gas and dust
		$1305 \pm 10$	Influenced by both gas and dust
		$3015 \pm 10$	Influenced by both gas and dust
		$3095 \pm 10$	Influenced by both gas and dust
(b)	4	$1115 \pm 10$	Influenced by dust
		$1305 \pm 10$	Influenced by both gas and dust
		$2505 \pm 10$	Influenced by dust
		$3095 \pm 10$	Influenced by both gas and dust
(c)	3	$1305 \pm 10$	Influenced by both gas and dust
		$3015 \pm 10$	Influenced by both gas and dust
		$3095 \pm 10$	Influenced by both gas and dust
(d)	3	$1115 \pm 10$	Influenced by dust
		$1305 \pm 10$	Influenced by both gas and dust
		$3095 \pm 10$	Influenced by both gas and dust

	Inversed Gas Concentration with Deviation and Its Maximum Relative Error (%)
Gas Concentration (%)	$γ = 1 %$	Maximum Relative Error (%)	$γ = 2 %$	Maximum Relative Error (%)	$γ = 5 %$	Maximum Relative Error (%)
0.1	$0.1 \pm 0.05$	50	$0.1 \pm 0.07$	70	$0.1 \pm 0.06$	60
0.5	$0.5 \pm 0.05$	10	$0.5 \pm 0.06$	12	$0.5 \pm 0.04$	8
1.0	$1.0 \pm 0.06$	6	$1.0 \pm 0.08$	8	$1.0 \pm 0.05$	5
2.0	$2.0 \pm 0.09$	4.5	$2.0 \pm 0.11$	5.5	$2.0 \pm 0.07$	3.5
5.0	$5.0 \pm 0.03$	0.6	$5.0 \pm 0.01$	0.2	$5.0 \pm 0.01$	0.2