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Numerical investigation of the two-dimensional gas temperature distribution based on tunable diode laser absorption spectroscopy

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Języki publikacji
EN
Abstrakty
EN
Based on tunable diode laser absorption spectroscopy and modified adaptive algebraic reconstruction technique, two-dimensional tomographic reconstruction was derived for the gas temperature distribution in the range of 600–1400 K in the controlled projections. It is explicitly shown that the quality of temperature reconstruction is heavily dependent on the relative sensitivity of the selected spectrum and the algorithm of modified adaptive algebraic reconstruction technique but independent of the complexity of the present field distribution. When the relative sensitivity is less than 1.5, the accuracy of reconstruction relates to the relative sensitivity of the selected spectrum and improves with the increase in relative sensitivity. When the relative sensitivity is larger than 1.5, the accuracy is mainly limited by the algorithm of modified adaptive algebraic reconstruction technique.
Czasopismo
Rocznik
Strony
183--198
Opis fizyczny
Bibliogr. 29 poz., rys., tab.
Twórcy
autor
  • Institute of Information Optics, Zhejiang Normal University, Jinhua 321004, PR China
autor
  • Institute of Information Optics, Zhejiang Normal University, Jinhua 321004, PR China
autor
  • Institute of Information Optics, Zhejiang Normal University, Jinhua 321004, PR China
Bibliografia
  • [1] LIU J.T., RIEKER G.B., JEFFRIES J.B., GRUBER M.R., CARTER C.D., MATHUR T., HANSON R.K., Near- -infrared diode laser absorption diagnostic for temperature and water vapor in a scramjet combustor, Applied Optics 44(31), 2005, pp. 6701–6711.
  • [2] TINGDONG CAI, GUISHI WANG, ZHENSONG CAO, WEIJUN ZHANG, XIAOMING GAO, Sensor for headspace pressure and H2O concentration measurements in closed vials by tunable diode laser absorption spectroscopy, Optics and Lasers in Engineering 58, 2014, pp. 48–53.
  • [3] TINGDONG CAI, GUANGZHEN GAO, YING LIU, Calibration-free sensor for pressure and H2O concentration in headspace of sterile vial using tunable diode laser absorption spectroscopy, Applied Optics 52(32), 2013, pp. 7682–7688.
  • [4] NICOLAS J.-C., BARANOV A.N., CUMINAL Y., ROUILLARD Y., ALIBERT C., Tunable diode laser absorption spectroscopy of carbon monoxide around 2.35 µm, Applied Optics 37(33), 1998, pp. 7906–7911.
  • [5] MILLER M.F., KESSLER W.J., ALLEN M.G., Diode laser-based air mass flux sensor for subsonic aeropropulsion inlets, Applied Optics 35(24), 1996, pp. 4905–4912. [6] WANG F., CEN K.F., LI N., JEFFRIES J.B., HUANG Q.X., YAN J.H., CHI Y., Two-dimensional tomography for gas concentration and temperature distributions based on tunable diode laser absorption spectroscopy, Measurement Science and Technology 21(4), 2010, article 045301.
  • [7] SATO M., NOMURA D., KITANO T., TSUNENARI T., NISHIDATE I., Variations in signal intensity with periodical temperature changes in vivo in rat brain: analysis using wide-field optical coherence tomography, Applied Optics 51(10), 2012, pp. 1436–1445.
  • [8] XINLIANG AN, KRAETSCHMER T., TAKAMI K., SANDERS S.T., LIN MA, WEIWEI CAI, XUESONG LI, ROY S., GORD J.R., Validation of temperature imaging by H2O absorption spectroscopy using hyperspectral tomography in controlled experiments, Applied Optics 50(4), 2011, pp. A29–A37.
  • [9] BROWN M.S., HERRING G.C., CABELL K., HASS N., BARHORST T.F., GRUBER M., Optical measurements at the combustor exit of the HIFiRE 2 ground test engine, 50th AIAA Aerospace Sciences Meeting Including the New Horizons Forum and Aerospace Exposition, 2012.
  • [10] WRIGHT P., GARCIA-STEWART C.A., CAREY S.J., HINDLE F.P., PEGRUM S.H., COLBOURNE S.M., TURNER P.J., HURR W.J., LITT T.J., MURRAY S.C., CROSSLEY S.D., OZANYAN K.B., MCCANN H., Toward in-cylinder absorption tomography in a production engine, Applied Optics 44(31), 2005, pp. 6578–6592.
  • [11] TERZIJA N., DAVIDSON J.L., GARCIA-STEWART C.A., WRIGHT P., OZANYAN K.B., PEGRUM S., LITT T.J., MCCANN H., Image optimization for chemical species tomography with an irregular and sparse beam array, Measurement Science and Technology 19(9), 2008, article 094007.
  • [12] WEIWEI CAI, C.F. KAMINSKI, Multiplexed absorption tomography with calibration-free wavelength modulation spectroscopy, Applied Physics Letters 104(15), 2014, article 154106.
  • [13] LIN MA, XUESONG LI, SANDERS S.T., CASWELL A.W., ROY S., PLEMMONS D.H., GORD J.R., 50-kHz-rate 2D imaging of temperature and H2O concentration at the exhaust plane of a J85 engine using hyperspectral tomography, Optics Express 21(1), 2013, pp. 1152–1162.
  • [14] LIN MA, WEIWEI CAI, CASWELL A.W., KRAETSCHMER T., SANDERS S.T., ROY S., GORD J.R., Tomographic imaging of temperature and chemical species based on hyperspectral absorption spectroscopy, Optics Express 17(10), 2009, pp. 8602–8613.
  • [15] JUNLING SONG, YANJI HONG, GUANGYU WANG, HU PAN, Algebraic tomographic reconstruction of two-dimensional gas temperature based on tunable diode laser absorption spectroscopy, Applied Physics B 112(4), 2013, pp. 529–537.
  • [16] XIN ZHOU, XIANG LIU, JEFFRIES J.B., HANSON R.K., Selection of NIR H2O absorption transitions for in-cylinder measurement of temperature in IC engines, Measurement Science and Technology 16(12), 2005, pp. 2437–2445.
  • [17] ALLEN M.G., Diode laser absorption sensors for gas-dynamic and combustion flows, Measurement Science and Technology 9(4), 1998, pp. 545–562.
  • [18] XIN ZHOU, XIANG LIU, JEFFRIES J.B., HANSON R.K., Development of a sensor for temperature and water concentration in combustion gases using a single tunable diode laser, Measurement Science and Technology 14(8), 2003, pp. 1459–1468.
  • [19] BRYNER E., SHARMA M., GOYNE C., MCDANIEL J., SNYDER M., KRAUSS R., MARTIN E., DISKIN G., Tunable diode laser absorption technique development for determination of spatially resolved water concentration and temperature, 48th AIAA Aerospace Sciences Meeting Including the New Horizons Forum and Aerospace Exposition, Odando, USA: AIAA, 2010, pp. 1–299.
  • [20] NING LI, CHUNSHENG WENG, Modified adaptive algebraic tomographic reconstruction of gas distribution from incomplete projection by a two-wavelength absorption scheme, Chinese Optics Letters 9(6), 2011, article 061201.
  • [21] SANE A., SATIJA A., LUCHT R.P., GORE J.P., Simultaneous CO concentration and temperature measurements using tunable diode laser absorption spectroscopy near 2.3 μm, Applied Physics B 117(1), 2014, pp. 7–18.
  • [22] SHAO J., LATHDAVONG L., KLUCZYNSKI P., LUNDQVIST S., AXNER O., Methodology for temperature measurements in water vapor using wavelength-modulation tunable diode laser absorption spectrometry in the telecom C-band, Applied Physics B 97(3), 2009, pp. 727–748.
  • [23] HANSEN P.C., SAXILD-HANSEN M., AIR tools – a MATLAB package of algebraic iterative reconstruction methods, Journal of Computational and Applied Mathematics 236(8), 2012, pp. 2167–2178.
  • [24] GORDON R., BENDER R., HERMAN G.T., Algebraic reconstruction techniques (ART) for three-dimensional electron microscopy and X-ray photography, Journal of Theoretical Biology 29(3), 1970, pp. 471–476.
  • [25] SAXILD-HANSEN M., AIR Tools – A MATLAB Package for Algebraic Iterative Reconstruction Techniques, Master’s Thesis, Technical University of Denmark, DTU, DK-2800 Kgs. Lyngby, Denmark, 2010.
  • [26] DEZHONG WANG, TIANGE ZHUANG, The measurement of 3-D asymmetric temperature field by using real time laser interferometric tomography, Optics and Lasers in Engineering 36(3), 2001, pp. 289–297.
  • [27] WEIWEI CAI, LIN MA, Hyperspectral tomography based on proper orthogonal decomposition as motivated by imaging diagnostics of unsteady reactive flows, Applied Optics 49(4), 2010, pp. 601–610.
  • [28] ABBAS M., MAJID A.A., ALI J.M., Positivity-preserving rational bi-cubic spline interpolation for 3D positive data, Applied Mathematics and Computation 234, 2014, pp. 460–476.
  • [29] LIN MA, WEIWEI CAI, Numerical investigation of hyperspectral tomography for simultaneous temperature and concentration imaging, Applied Optics 47(21), 2008, pp. 3751–3759.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-03b43d7e-53f6-40a8-ae5f-a9af628a4371
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