International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B7. Istanbul 2004
relative error is 11 %, 9 % and 5 % for AVHRR,
VEGETATION and MODIS, respectively. However, RDVI,
OSAVI and SAVI indices show a similar sensitivity in the
bands of the same sensor. Indeed, relative error is 9% for
AVHRR, 7 % for VEGETATION and 4 % for MODIS.
With the difference of the four preceding indices, the NDVI
shows a similar relative error between AVHRR and
VEGETATION. In the extreme ozone concentration and a
very dense cover, the relative error on the NDVI is 8 %. If we
consider the same conditions, we show that the MODIS bands
normalize better the ozone absorption effect on this index; the
relative error does not exceed 4%.
The indices developed to correct the atmospheric effects
(ARVI and TSARVI) normalize correctly the variations of the
ozone concentration in the atmosphere. In the extreme ozone
concentration (0,959 g/cm3) and a very dense forest cover, the
relative error on the ARVI (y = 0.5) does not exceed 7 %
independently from the sensor characteristics. In the same
condition, the relative error on the TSARVI (y = 0.5) does not
exceed 5 % and 3 %, respectively, for VEGETATION and
MODIS. We can conclude that the TSARVI index is the least
affected by the atmospheric effects. Also, GEMI index has a
fow sensitivity to the ozone absorption effect. For a dense
cover and strong ozone concentration in the atmosphere, the
50
45 |
40 |
MSR
Relative Mean Error ( % )
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0 i LIZE
relative error on this index is 6 %, 2 % and 1% for AVHRR,
VEGETATION and MODIS, respectively. According to
Asalhi (2003) and Bannari er al. (2000), the GEMI is less
sensitive to the water vapour absorption and resistant to the
aerosols diffusion.
4. Conclusions
Figure 1 summarizes the impact of a strong ozone
concentration (0,959 g/cm3) on different vegetation indices
considering a very dense forest cover (100 %). Except for the
EVI, MSR and GARI, all used vegetation indices are
characterized in general by a good resistance to the ozone
absorption particularly in MODIS channels. This sensor
seems to avoid perfectly the ozone absorption bands.
Furthermore, the relative error is higher for the AVHRR
sensor and relatively higher for the VEGETATION sensor. In
the broadband AVHRR sensor, the relative errors vary
between 6 % and 23% for the most resistant (GEMI) and the
most sensitive index (MSR). Also, this figure underlines the
perfect resistance of the TSARVI and GEMI to the ozone
absorption considering the MODIS and VEGETATION
Sensors.
O AVHRR
EJ] VEGETATION
E] MODIS
Figure 1: Sensitivity of different vegetation indices to ozone concentration (0,959 g/cm3) considering a dense forest cover (100 %).
Acknowledgment
The authors would like to thank the Natural Sciences and
Engineering Research Council of Canada (NSERC) for
the financial support.
References
Asalhi, H., 2003, Analyse de la sensibilité des indices de
végétation au-dessus d'un couvert forestier de sapin :
étude comparative à partir des données de simulations
804
entre MODIS-EOS, VEGETATION-SPOT et AVHRR-
NOAA. Thèse de maîtrise, Département de géographie,
Université d’Ottawa, Ottawa, Ontario, Canada, 153
pages.
Bannari, A, Teillet, P.M., Leckie, D.G. et Fedosejevs, G., 2000,
Impact des conditions internes et externes aux couverts
forestiers sur les indices spectraux dérivés de AVHRR.
La revue Télédétection, vol. 1, n°. 3, p. 157-181.
Bannari, A, Royer, A. et Morin, D., 1997, L'indice de
végétation TSARVI : Transformed soil atmospherically
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