Laser & Optoelectronics Progress, Volume. 59, Issue 23, 2320002(2022)
Reconstruction Technology for Three-Dimensional Emission Computerized Tomography Based on Linear Interpolation Theory
References(17)
[1] Wang Q, Yu T, Liu H C et al. Optimization of camera arrangement for volumetric tomography with constrained optical access[J]. Journal of the Optical Society of America B, 37, 1231-1239(2020).
[2] Wang J, Guo Z Y, Nie L et al. High spatial resolution computed tomography of chemiluminescence with densely sampled parallel projections[J]. Optics Express, 27, 21050-21068(2019).
[3] Denisova N, Tretyakov P, Tupikin A. Emission tomography in flame diagnostics[J]. Combustion and Flame, 160, 577-588(2013).
[4] Ishino Y, Ohiwa N. Three-dimensional computerized tomographic reconstruction of instantaneous distribution of emission intensity in turbulent premixed flames[J]. Lean Combustion Technology II, 25-29(2001).
[5] Ishino Y, Ohiwa N. Three-dimensional computerized tomographic reconstruction of instantaneous distribution of chemiluminescence of a turbulent premixed flame[J]. JSME International Journal Series B, 48, 34-40(2005).
[6] Floyd J, Kempf A M. Computed Tomography of Chemiluminescence (CTC): high resolution and instantaneous 3-D measurements of a Matrix burner[J]. Proceedings of the Combustion Institute, 33, 751-758(2011).
[7] Gilabert G, Lu G, Yan Y. Three-dimensional tomographic reconstruction of the luminosity distribution of a combustion flame[J]. IEEE Transactions on Instrumentation and Measurement, 56, 1300-1306(2007).
[8] Sun N. Study on reconstructed methods of three-dimensional optical volume computerized tomography[D](2013).
[9] Wang J, Song Y, Li Z H et al. Multi-directional 3D flame chemiluminescence tomography based on lens imaging[J]. Optics Letters, 40, 1231-1234(2015).
[10] Cai W W, Li X S, Ma L. Practical aspects of implementing three-dimensional tomography inversion for volumetric flame imaging[J]. Applied Optics, 52, 8106-8116(2013).
[11] Li X S, Ma L. Volumetric imaging of turbulent reactive flows at kHz based on computed tomography[J]. Optics Express, 22, 4768-4778(2014).
[12] Liu Y, Lu H J, Chang D F. Indoor smoke visualization based on the improved ray-casting algorithm[J]. Laser & Optoelectronics Progress, 58, 0410005(2021).
[13] Dong C Y. The design of marine-acoustic-tomography database and visualization software system[D](2021).
[14] Li X Y, Ma H M, Wang Q et al. Three dimensional interpolation method of pulmonary electrical impedance tomography based on contour shape[J]. Journal of Electronic Measurement and Instrumentation, 35, 89-97(2021).
[15] Jin Y, Song Y, Wang W C et al. An improved calculation model of weight coefficient for three-dimensional flame chemiluminescence tomography based on lens imaging theory[J]. Proceedings of SPIE, 10026, 1002612(2016).
[16] Cai W W, Li X S, Li F et al. Numerical and experimental validation of a three-dimensional combustion diagnostic based on tomographic chemiluminescence[J]. Optics Express, 21, 7050-7064(2013).
[17] Wang J, Zhang W G, Zhang Y H et al. Camera calibration for multidirectional flame chemiluminescence tomography[J]. Optical Engineering, 56, 041307(2016).
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Mingzhe Li, Jia Wang, Dangjuan Li, Mi Zhou, Junxia Cheng, Shenjiang Wu. Reconstruction Technology for Three-Dimensional Emission Computerized Tomography Based on Linear Interpolation Theory[J]. Laser & Optoelectronics Progress, 2022, 59(23): 2320002
Paper Information
Category: Optics in Computing
Received: Feb. 21, 2022
Accepted: Jun. 13, 2022
Published Online: Dec. 9, 2022
The Author Email: Wu Shenjiang (bxait@xatu.edu.cn)
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