142
The classifiers used in this study demonstrated some differences when used in SW and BISE algorithms,
suggesting the choice of compositing classifier is of concern. But on the other hand, the temporal profiles of different
classifiers showed some similarities in seasonal variations with vegetation, indicating the choice of the classifier may
not be critical if the only qualitative studies involved. More differences were found between compositing algorithms
than between classifiers, which suggested that the choice of classifier is less important than the choice of composing
algorithms, although a good classifier would certainly increase the liability and the meaning of composited remote
sensing products.
In conclusion, the SW showed substantial improvement in composi ting multitemporal AVHRR data by ret aining
more valuable data while minimizing the high frequency noise. For low vegetation covered earth surfaces, the MSAVI
and SAVI appeared to be the better classifiers, while for high vegetation densities any of the classifiers (tested in this
study) can be used in compositing. It is more important, however, to choose the appropriate composing algorithms than
to choose their classifiers. It should be pointed out, however, that any compositing algorithm can only produces, from
whatever data it is given, a subset that the algorithm ’thinks’ it is the best. Other errors such as those due to geometric
registration would most likely remain after compositing.
Acknowledgements-. The authors are grateful to the USDA ARS Water Conservation Laboratory in Phoenix for financial
support and Southwest Watershed Research Center in Tucson for providing very convenient working environment. The
author was also grateful to Cabot F. and LERTS for providing the AVHRR data. This work is also a part of the NASA
Interdisciplinary Research Program in Earth Sciences (NASA Reference Number IDP-88-086) at the University of
Arizona (USA) and LERTS (Toulouse, France).
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