2003
DOI: 10.1080/0143116021000033267
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Airborne forest fire mapping with an adaptive infrared sensor

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Cited by 9 publications
(4 citation statements)
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“…This can cause, for example, the radiant power contribution from a fire to vary between the spectral bands of the sensor, with the result that the fire may contribute proportionally more to the MIR band signal of a ‘fire’ pixel than to the TIR band for example (with the reverse likely in the neighbouring pixel). Such effects invalidate the bi‐spectral model's assumption that the fire fractional area is consistent across the MIR and TIR spectral bands of the fire pixel, and thus perturb the retrieval of fire fractional area and temperature [ Oertel et al , 2003; Zhukov et al , 2005a, 2005b]. However, careful application of the bi‐spectral approach can mitigate the consequences of interchannel spatial misregistration and PSF differences, generally by analysing the cumulative signal of clusters of spatially contiguous fire pixels rather than the individual fire pixels themselves [ Zhukov et al , 2005b].…”
Section: Remote Sensing Fire Radiative Powermentioning
confidence: 99%
“…This can cause, for example, the radiant power contribution from a fire to vary between the spectral bands of the sensor, with the result that the fire may contribute proportionally more to the MIR band signal of a ‘fire’ pixel than to the TIR band for example (with the reverse likely in the neighbouring pixel). Such effects invalidate the bi‐spectral model's assumption that the fire fractional area is consistent across the MIR and TIR spectral bands of the fire pixel, and thus perturb the retrieval of fire fractional area and temperature [ Oertel et al , 2003; Zhukov et al , 2005a, 2005b]. However, careful application of the bi‐spectral approach can mitigate the consequences of interchannel spatial misregistration and PSF differences, generally by analysing the cumulative signal of clusters of spatially contiguous fire pixels rather than the individual fire pixels themselves [ Zhukov et al , 2005b].…”
Section: Remote Sensing Fire Radiative Powermentioning
confidence: 99%
“…Airborne sensors have also been used extensively in support of fire management in the United States, and to a lesser extent in support of fire science studies in different geographic regions (Kaufman, Kleidman, & King, 1998;King, Platnick, Moeller, Revercomb, & Chu, 2003;Oertel et al, 2003;Riggan et al, 2004). Use of airborne platforms for quantitative fire imaging requires that sensors operating in the middle-infrared (≈4 μm) spectral region have a high dynamic range because it is in this region that fires emit most of their radiation.…”
Section: Introductionmentioning
confidence: 99%
“…The methodology has proven to provide successfully monitoring results over 2000 km 2 in Central Italy (Lazio) allowing to map forest burnt areas with an accuracy compatible with 1:10000 scale level. Remote sensing by aerial light vectors can be effi ciently (in terms of imagery quality and cost) used to map and qualify with high accuracy damages on distinctive spots, and it is also particularly suitable for calibrating remotely sensed imagery of lower geometric resolu tion (Oertel et al 2003).…”
Section: Aerial Assessment: the Simib Projectmentioning
confidence: 99%