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Erschienen in:
Theoretical Background of Thermal Infrared Remote Sensing Kapitel lesen Erstes Kapitel lesen

2013 | OriginalPaper | Buchkapitel

3. Thermal Infrared Spectroscopy in the Laboratory and Field in Support of Land Surface Remote Sensing

verfasst von : Christoph A. Hecker, Thomas E. L. Smith, Beatriz Ribeiro da Luz, Martin J. Wooster

Erschienen in: Thermal Infrared Remote Sensing

Verlag: Springer Netherlands

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Abstract

Thermal infrared (TIR) spectra of Earth surface materials are used in a wide variety of applications. These applications can fall into either of two groups: (a) where the TIR emissivity spectra themselves are the primary interest, and are used to determine the chemical/physical parameters of minerals and rocks, soil, vegetation and man-made materials, or (b) where the primary interest is in the temperature of the objects under study, and where emissivity spectra are required inorder to best determine kinetic from radiant temperature. Unlike visible-near infrared (VNIR) and shortwave infrared (SWIR) instruments, TIR spectroscopy instrumentation often requires customization in order to acquire reliable and reproducible data, making thermal spectroscopy a potentially complex process. Within this chapter we intend to provide a simple starting point for the new user of thermal infrared spectroscopy, and a synoptic overview of the technique for the more experienced practitioner. We discuss the theoretical background, give examples of instrument setups and provide typical measurement scenarios for a number of land applications.

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Vorheriges Kapitel Geometric Calibration of Thermographic Cameras
Nächstes Kapitel Challenges and Opportunities for UAV-Borne Thermal Imaging
Literatur
Anderson, JR, Hardy EE, Roach JT, Witmer RE (1976) A land use and land cover classification system for use with remote sensor data. Geologic survey professional paper, USGS, Washington, DC, p28
Bassani C, Cavalli RM, Cavalcante F, Cuomo V, Palombo A, Pascucci S et al (2007) Deterioration status of asbestos-cement roofing sheets assessed by analyzing hyperspectral data. Remote Sens Environ 109(3):361–378. doi:10.​1016/​j.​rse.​2007.​01.​014 CrossRef
Bower N, Lynch MJ, Knuteson RO, Revercomb HE (2001) High spectral resolution land surface temperature and emissivity measurement in the thermal infrared using Fourier transform spectroscopy. In: Sawchuk A (ed) Optical remote sensing, vol 52 of OSA trends in optics and photonics. Optical Society of America, paper OWA5. http://​www.​opticsinfobase.​org/​abstract.​cfm?​URI=​ORS-2001-OWA5
Burrows JP, Platt U, Borrell P (2011) The remote sensing of tropospheric composition from space, Physics of earth and space environments 15. Springer, HeidelbergCrossRef
Christensen PR, Bandfield JL, Hamilton VE, Howard DA, Lane MD, Piatek JL et al (2000) A thermal emission spectral library of rock-forming minerals. J Geophys Res Planets 105(E4):9735–9739CrossRef
Clark RN, Swayze GA, Wise RA, Livo KE, Hoefen TM, Kokaly RF et al (2007) USGS digital spectral library splib06a. U.S. Geological Survey, Denver
Coll C, Caselles V, Valor E, Rubio E (2003) Validation of temperature-emissivity separation and split-window methods from TIMS data and ground measurements. Remote Sens Environ 85(2):232–242. doi:10.​1016/​s0034-4257(03)00003-8 CrossRef
Dash P, Göttsche FM, Olesen FS, Fischer H (2002) Land surface temperature and emissivity estimation from passive sensor data: theory and practice-current trends. Int J Remote Sens 23(13):2563–2594. doi:10.​1080/​0143116011011504​1 CrossRef
Gillespie A, Rokugawa S, Matsunaga T, Cothern JS, Hook SJ, Kahle AB (1998) A temperature and emissivity separation algorithm for Advanced Spaceborne Thermal Emission and Reflection Radiometer (ASTER) images. Geosci Remote Sens IEEE Trans 36(4):1113–1126CrossRef
Hecker C, Hook SJ, van der Meijde M, Bakker W, van der Werff H, Wilbrink H et al (2011) Thermal infrared spectrometer for earth science remote sensing applications-instrument modifications and measurement procedures. Sensors 11(11):10981–10999 doi:10.​3390/​s111110981 CrossRef
Hook SJ, Kahle AB (1996) The micro Fourier transform interferometer (μFTIR) – a new field spectrometer for acquisition of infrared data of natural surfaces. Remote Sens Environ 56(3):172–181. doi:10.​1016/​0034-4257(95)00231-6 CrossRef
Hoover G, Kahle AB (1987) A thermal emission spectrometer for field use. Photogramm Eng Remote Sens 53:627–632
Horton KA, Johnson JR, Lucey PG (1998) Infrared measurements of pristine and disturbed soils 2. Environmental effects and field data reduction. Remote Sens Environ 64(1):47–52CrossRef
Hulley GC, Hook SJ, Manning E, Lee SY, Fetzer E (2009) Validation of the Atmospheric Infrared Sounder (AIRS) version 5 land surface emissivity product over the Namib and Kalahari deserts. J Geophys Res 114(D19), D19104. doi:10.​1029/​2009jd012351 CrossRef
Hulley GC, Hook SJ, Baldridge AM (2010) Investigating the effects of soil moisture on thermal infrared land surface temperature and emissivity using satellite retrievals and laboratory measurements. Remote Sens Environ 114(7):1480–1493. doi:10.​1016/​j.​rse.​2010.​02.​002 CrossRef
Huntington J, Whitbourn L, Mason P, Berman M, Schodlok MC (2010) HyLogging – voluminous industrial-scale reflectance spectroscopy of the earth’s subsurface. In: Huntinton JF (ed) Art, science and applications of reflectance spectroscopy symposium, Boulder, 23–25 Feb 2010, II, p 14
Jacob F, Petitcolin F, Schmugge T, Vermote É, French A, Ogawa K (2004) Comparison of land surface emissivity and radiometric temperature derived from MODIS and ASTER sensors. Remote Sens Environ 90(2):137–152. doi:10.​1016/​j.​rse.​2003.​11.​015 CrossRef
Kahle AB, Madura DP, Soha JM (1980) Middle infrared multispectral aircraft scanner data: analysis for geological applications. Appl Opt 19(14):2279–2290CrossRef
Kirkland L, Herr K, Keim E, Adams P, Salisbury JW, Hackwell J et al (2002) First use of an airborne thermal infrared hyperspectral scanner for compositional mapping. Remote Sens Environ 80(3):447–459CrossRef
Korb AR, Dybwad P, Wadsworth W, Salisbury JW (1996) Portable Fourier transform infrared spectroradiometer for field measurements of radiance and emissivity. Appl Opt 35(10):1679–1692CrossRef
Korb AR, Salisbury JW, D’Aria DM (1999) Thermal-infrared remote sensing and Kirchhoff’s law 2. Field measurements. J Geophys Res Solid Earth 104(B7):15339–15350CrossRef
Lammoglia T, de Souza Filho CR (2011) Spectroscopic characterization of oils yielded from Brazilian offshore basins: potential applications of remote sensing. Remote Sens Environ 115(10):2525–2535. doi:10.​1016/​j.​rse.​2011.​04.​038 CrossRef
Lee RJ (2011) Thermal emission spectroscopy of silicate glasses and melts: applications to remote sensing of glassy volcanic environments. Ph.D., Univeristy of Pittsburgh, Pittsburgh
Lindermeir E, Haschberger P, Tank V, Dietl H (1992) Calibration of a Fourier transform spectrometer using three blackbody sources. Appl Opt 31(22):4527–4533CrossRef
Lyon RJP (1965) Analysis of rocks by spectral infrared emission (8–25 microns). Econ Geol 60:715–736CrossRef
Minnett PJ, Szczodrak M, Key EL (2005) Surface-based infrared interferometers – versatile sensors for the IPY. In: Proceedings of the 8th conference on polar meteorology and oceanography, San Diego, 10–13 Jan 2005
Mitraka Z, Chrysoulakis N, Kamarianakis Y, Partsinevelos P, Tsouchlaraki A (2011) Improving the estimation of urban surface emissivity based on sub-pixel classification of high resolution satellite imagery. Remote Sens Environ 117:125–134. doi:10.​1016/​j.​rse.​2011.​06.​025 CrossRef
Nicodemus FE (1965) Directional reflectance and emissivity of an opaque surface. Appl Opt 4:767–773CrossRef
Pascucci S, Bassani C, Palombo A, Poscolieri M, Cavalli R (2008) Road asphalt pavements analyzed by airborne thermal remote sensing: preliminary results of the Venice highway. Sensors 8(2):1278–1296CrossRef
Ramsey MS (2003) Mapping the city landscape from space: the advanced spaceborne thermal emission and reflectance radiometer (ASTER) urban environmental monitoring program. In: Heiken G, Fakundiny R, Sutter J (eds) Earth science in the city: a reader. AGU, Washington, DC, pp 337–361CrossRef
Ramsey MS, Fink JH (1999) Estimating silicic lava vesicularity with thermal remote sensing: a new technique for volcanic mapping and monitoring. Bull Volcanol 61(1):32–39. doi:10.​1007/​s004450050260 CrossRef
Ribeiro da Luz B, Crowley JK (2007) Spectral reflectance and emissivity features of broad leaf plants: prospects for remote sensing in the thermal infrared (8.0–14.0 [mu]m). Remote Sens Environ 109(4):393–405. doi:10.​1016/​j.​rse.​2007.​01.​008 CrossRef
Ruff SW, Christensen PR, Barbera PW, Anderson DL (1997) Quantitative thermal emission spectroscopy of minerals: a laboratory technique for measurement and calibration. J Geophys Res 102(B7):14899–14913CrossRef
Salisbury JW (1998) Spectral measurements field guide. Defense Technology Information Center, Fort Belvoir, p 91
Salisbury JW, D’Aria DM (1992) Emissivity of terrestrial materials in the 8–14 μm atmospheric window. Remote Sens Environ 42(2):83–106CrossRef
Salisbury JW, Walter LS, Vergo N, D’Aria DM (1991) Infrared (2.1–25 μm) spectra of minerals. The Johns Hopkins University Press, Baltimore/London
Salisbury JW, Wald A, D’Aria DM (1994) Thermal-infrared remote sensing and Kirchhoff’s Law 1. Laboratory measurements. J Geophys Res Solid Earth 99(B6):11897–11911CrossRef
Salvaggio C, Miller CJ (2001) Comparison of field- and laboratory-collected midwave and longwave infrared emissivity spectra/data reduction techniques. In: Proceedings of the SPIE 4381, Algorithms for multispectral, hyperspectral, and ultraspectral imagery VII, Orlando, 2001, pp 549–558
Sobrino JA, Cuenca J (1999) Angular variation of thermal infrared emissivity for some natural surfaces from experimental measurements. Appl Opt 38(18):3931–3936CrossRef
Thomas HE, Watson IM, Kearney C, Carn SA, Murray SJ (2009) A multi-sensor comparison of sulphur dioxide emissions from the 2005 eruption of Sierra Negra volcano, Galápagos Islands. Remote Sens Environ 113(6):1331–1342. doi:10.​1016/​j.​rse.​2009.​02.​019 CrossRef
Ullah S, Schlerf M, Skidmore AK, Hecker C (2012) Identifying plant species using mid-wave infrared (2.5–6 μm) and thermal infrared (8–14 μm) emissivity spectra. Remote Sens Environ 118:95–102. doi:10.​1016/​j.​rse.​2011.​11.​008 CrossRef
Vaughan RG, Calvin WM, Taranik JV (2003) SEBASS hyperspectral thermal infrared data: surface emissivity measurement and mineral mapping. Remote Sens Environ 85(1):48–63CrossRef
Vaughan RG, Hook SJ, Calvin WM, Taranik JV (2005) Surface mineral mapping at Steamboat Springs, Nevada, USA, with multi-wavelength thermal infrared images. Remote Sens Environ 99(1–2):140–158CrossRef
Vincent RK, Hunt GR (1968) Infrared reflectance from mat surfaces. Appl Opt 7:53–59CrossRef
Xu W, Wooster MJ, Grimmond CSB (2008) Modelling of urban sensible heat flux at multiple spatial scales: a demonstration using airborne hyperspectral imagery of Shanghai and a temperature–emissivity separation approach. Remote Sens Environ 112(9):3493–3510. doi:10.​1016/​j.​rse.​2008.​04.​009 CrossRef
Metadaten
Titel
Thermal Infrared Spectroscopy in the Laboratory and Field in Support of Land Surface Remote Sensing
verfasst von
Christoph A. Hecker
Thomas E. L. Smith
Beatriz Ribeiro da Luz
Martin J. Wooster
Copyright-Jahr
2013
Verlag
Springer Netherlands
Buch
Thermal Infrared Remote Sensing

Print ISBN: 978-94-007-6638-9

Electronic ISBN: 978-94-007-6639-6

Copyright-Jahr: 2013

DOI
https://doi.org/10.1007/978-94-007-6639-6_3