Abstract
In this article it is shown that the multifractal microcanonical formalism (herein referred to as MMF) has strong potential for bringing new solutions to a known problem in the analysis of some remotely sensed datasets: the determination of fire plumes in NOAA–AVHRR data. It has been proven that NOAA–AVHRR data can be used to detect plumes caused by fire accidents of different kinds. This work builds on previous studies and uses the MMF to introduce novel methods for the determination of plumes. The MMF can be used to derive geometrical superstructures (like certain multifractal topological manifolds and most importantly the so‐called reduced signals) that are able to deal with the multiscale properties of turbulent geophysical fluid flows. These multiscale properties make use of the spatial distribution of grey‐level values in the datasets and they are used in conjunction with previous pixel‐based descriptors to enhance the determination of plume pixels.
Acknowledgement
This work was done in the framework of the PLUMESAT project (‘Use of a satellite ground receiving station for the detection and monitoring of fires and plumes caused by major natural and man‐made disasters’). The PLUMESAT project is funded by:
The ‘Competitveness’ Programme, Action 4.3.6.1.γ of the General Secretary of Research and Technology of the Ministry of Development of Greece. | |||||
The ‘Platon 2005’ Integrated Action Programme (PAI) of the French Ministry of Foreign Affairs, through EGIDE. |