Development of a multi-temporal Kalman filter approach to geostationary active fire detection & fire radiative power (FRP) estimation

Most active fire detection algorithms applied to data from geostationary Earth Observation (EO) satellites are adjustments of those originally developed for polar-orbiting systems, and thus the high temporal imaging frequencies offered from geostationary systems are often not fully utilized within s...

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Bibliographic Details
Published in:Remote sensing of environment 2014-09, Vol.152, p.392-412
Main Authors: Roberts, G., Wooster, M.J.
Format: Article
Language:English
Subjects:
Active fire
Algorithm
Algorithms
Animal, plant and microbial ecology
Applied geophysics
Biological and medical sciences
Biomass burning
Earth sciences
Earth, ocean, space
Estimates
Exact sciences and technology
Fiber reinforced plastics
Fire detection
Fire radiative power (FRP)
Fires
Fuel consumption
Fundamental and applied biological sciences. Psychology
General aspects. Techniques
Internal geophysics
Kalman filters
MODIS
Pixels
SEVIRI
Teledetection and vegetation maps
Temporal logic
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Summary:Most active fire detection algorithms applied to data from geostationary Earth Observation (EO) satellites are adjustments of those originally developed for polar-orbiting systems, and thus the high temporal imaging frequencies offered from geostationary systems are often not fully utilized within such detection approaches. Here we present a new active fire detection algorithm that fully exploits geostationary data's temporal dimension, including both for detecting actively burning fires and quantifying their fire radiative power (FRP). The approach uses a robust matching algorithm to model each pixels diurnal temperature cycle (DTC) in the middle infra-red (MIR) spectral band, the most important band for active fire detection. For each pixel, a Kalman filter (KF) is used to blend the set of basis DTCs with the actual geostationary observations during times of confirmed cloud- and fire-free measurements, allowing for estimates of the pixels true non-fire ‘background’ signal to be provided throughout the day, even when a fire maybe present. This is different to the standard ‘spatial contextual’ approach, where the non-fire background signal is estimated from nearby non-fire pixels. A series of spectral thresholds are then applied to the analyzed pixel in order to identify whether the actual observation departs sufficiently from the estimated non-fire signal to confidently suggest that the pixel contains an active fire. If it does, the difference between the fire pixel and non-fire background signal estimate in the MIR is used to estimate the fire radiative power (FRP) output. We apply this new ‘Kalman Filter Algorithm’ (KFA) to one month of African imagery acquired by the Spinning Enhanced Visible and Infrared Imager (SEVIRI), which is carried onboard the geostationary Meteosat satellite. We compare the resulting active fire detections and FRPs to those produced using the prototype (offline) version of the ‘spatial contextual’ based ‘Fire Thermal Anomalies’ (FTA) algorithm, here termed the pFTA, now used to generate the operational SEVIRI FRP-PIXEL product in the EUMETSAT Land Surface Analysis Satellite Applications Facility (http://landsaf.meteo.pt/), and also compare results to simultaneous detections from the MODIS MOD14/MYD14 active fire products. The KFA shows some advantages over the pFTA algorithm, detecting a greater number of fire pixels, up to ~80% more at the peak of the diurnal fire cycle. These additional fire pixels are primarily low FRP fires
ISSN:0034-4257
1879-0704
DOI:10.1016/j.rse.2014.06.020