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Vegetation fires have become an increasing problem in tropical environments as a consequence of socioeconomic pressures and subsequent land-use change. In response, fire management systems are being developed. This study set out to determine the relationships between two aspects of the fire problems in western Indonesia and Malaysia, and two components of the Canadian Forest Fire Weather Index System. The study resulted in a new method for calibrating components of fire danger rating systems based on satellite fire detection (hotspot) data. Once the climate was accounted for, a problematic number of fires were related to high levels of the Fine Fuel Moisture Code. The relationship between climate, Fine Fuel Moisture Code, and hotspot occurrence was used to calibrate Fire Occurrence Potential classes where low accounted for 3% of the fires from 1994 to 2000, moderate accounted for 25%, high 26%, and extreme 38%. Further problems arise when there are large clusters of fires burning that may consume valuable land or produce local smoke pollution. Once the climate was taken into account, the hotspot load (number and size of clusters of hotspots) was related to the Fire Weather Index. The relationship between climate, Fire Weather Index, and hotspot load was used to calibrate Fire Load Potential classes. Low Fire Load Potential conditions (75% of an average year) corresponded with 24% of the hotspot clusters, which had an average size of 30% of the largest cluster. In contrast, extreme Fire Load Potential conditions (1% of an average year) corresponded with 30% of the hotspot clusters, which had an average size of 58% of the maximum. Both Fire Occurrence Potential and Fire Load Potential calibrations were successfully validated with data from 2001. This study showed that when ground measurements are not available, fire statistics derived from satellite fire detection archives can be reliably used for calibration. More importantly, as a result of this work, Malaysia and Indonesia have two new sources of information to initiate fire prevention and suppression activities. 相似文献
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William J. de Groot Robert D. Field Michael A. Brady Orbita Roswintiarti Maznorizan Mohamad 《Mitigation and Adaptation Strategies for Global Change》2007,12(1):165-180
Forest and land fires in Southeast Asia have many social, economic, and environmental impacts. Tropical peatland fires affect
global carbon dynamics, and haze from peat fires has serious negative impacts on the regional economy and human health. To
mitigate these fire-related problems, forest and land management agencies require an early warning system to assist them in
implementing fire prevention and management plans before fire problems begin. Fire Danger Rating Systems (FDRS) were developed
for Indonesia and Malaysia to provide early warning of the potential for serious fire and haze events. In particular, they
identify time periods when fires can readily start and spread to become uncontrolled fires and time periods when smoke from
smouldering fires will cause an unacceptably high level of haze. The FDRS were developed by adapting components of the Canadian
Forest Fire Danger Rating System, including the Canadian Forest Fire Weather Index (FWI) System and the Canadian Forest Fire
Behavior Prediction (FBP) System, to local vegetation, climate, and fire regime conditions. A smoke potential indicator was
developed using the Drought Code (DC) of the FWI System. Historical air quality analysis showed that the occurrence of severe
haze events increased substantially when DC was above 400. An ignition potential indicator was developed using the Fine Fuel
Moisture Code (FFMC) of the FWI System. Historical hot spot analysis, grass moisture, and grass ignition studies showed that
fire occurrence and the ability for grass fires to start and spread dramatically increased when FFMC > 82. The Initial Spread
Index (ISI) of the FWI System was used to develop a difficulty of control indicator for grassland fires, a fuel type that
can exhibit high rates of spread and fire intensity. This ISI-based indicator was developed using the grass fuel model of
the FBP System, along with a standard grass fuel load and curing level estimated from previous Indonesian studies. Very high
fire intensity is expected in grasslands when ISI ≥ 6. To provide early warning, the FDRS identifies classes of increasing
fire danger as the FFMC, DC, and ISI approach these key threshold values. The Indonesian FDRS is now operated nationally at
the Indonesian Meteorological and Geophysical Agency. The Malaysian Meteorological Service operates the Malaysian FDRS and
displays regional outputs for the Association of Southeast Asian Nations. The FDRS are being used by forestry, agriculture,
environment, and fire and rescue agencies to develop and implement fire prevention, detection, and suppression plans. 相似文献
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