Application of Landsat ETM+ and OLI Data for Foliage Fuel Load Monitoring Using Radiative Transfer Model and Machine Learning Method

Quan, Xingwen; Li, Yanxi; He, Bin; Cary, Geoffrey J.; Lai, Gengke

doi:10.1109/jstars.2021.3062073

Cited by 28 publications

(5 citation statements)

References 91 publications

(117 reference statements)

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“…where ρ BLUE is MODIS data band 01, ρ RED is MODIS data band 02, ρ NIR is MODIS data band 03, and ρ SWIR is MODIS data band 07. In the upper model, PROGeoSAIL, the FMC estimate formula is [33,34]…”

Section: Sensitivity Analysismentioning

confidence: 99%

Estimation of Forest Canopy Fuel Moisture Content in Dali Prefecture by Combining Vegetation Indices and Canopy Radiative Transfer Models from MODIS Data

Yang,

Tang,

et al. 2024

Forests

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Forest canopy fuel moisture content (FMC) is a critical factor in assessing the vulnerability of a specific area to forest fires. The conventional FMC estimation method, which relies on look-up tables and loss functions, cannot to elucidate the relationship between FMC and simulated data from look-up tables. This study proposes a novel approach for estimating FMC by combining enhanced vegetation index (EVI) and normalized difference moisture index (NDMI). The method employs the PROSAIL + PROGeoSAIL two-layer coupled radiation transfer model to simulate the vegetation index, the water index, and the FMC value, targeting the prevalent double-layer structure in the study area’s vegetation distribution. Additionally, a look-up table is constructed through numerical analysis to investigate the relationships among vegetation indices, water indices, and FMC. The results reveal that the polynomial equations incorporating vegetation and water indices as independent variables exhibit a strong correlation with FMC. Utilizing the EVI–NDMI joint FMC estimation method enables the direct estimation of FMC. The collected samples from Dali were compared with the estimated values, revealing that the proposed method exhibits superior accuracy (R2 = 0.79) in comparison with conventional FMC estimation methods. In addition, we applied this method to estimate the FMC in the Chongqing region one week before the 2022 forest fire event, revealing a significant decreasing trend in regional FMC leading up to the fire outbreak, highlighting its effectiveness in facilitating pre-disaster warnings.

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Section: Sensitivity Analysismentioning

confidence: 99%

Estimation of Forest Canopy Fuel Moisture Content in Dali Prefecture by Combining Vegetation Indices and Canopy Radiative Transfer Models from MODIS Data

Yang,

Tang,

et al. 2024

Forests

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“…Topography can play a key role in governing bushfire severity patterns over a landscape [5], [10]- [14]. Many studies have identified that climate and fuel variables significantly influence bushfire severity [10], [15]- [17] but the situation is complex in hilly landscapes. In a hilly region, topography can not only govern fire behaviour but also influence the local micro-climate and fuel distribution of the area [12], [18], [19].…”

Section: Introductionmentioning

confidence: 99%

Characterizing Topographic Influences of Bushfire Severity Using Machine Learning Models: A Case Study in a Hilly Terrain of Victoria, Australia

Sharma

Aryal

Shao

et al. 2023

IEEE J. Sel. Top. Appl. Earth Observations Remote Sensing

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Topography plays a significant role in determining bushfire severity over a hilly landscape. However, complex interrelationships between topographic variables and bushfire severity are difficult to quantify using traditional statistical methods. More recently, different Machine Learning (ML) models are becoming popular in characterising complex relationships between different environmental variables. Yet, few studies have specifically evaluated the suitability of ML models in predictive bushfire severity analysis. Hence, the aim of this research is twofold. First, to determine suitable ML models by assessing their performances in bushfire severity predictions using remote sensing data analytics, and second to identify and investigate topographic variables influencing bushfire severity. The results showed that Random Forest (RF) and Gradient Boosting (GB) models had their distinct advantages in predictive modelling of bushfire severity. RF model showed higher precision (86% to 100%) than GB (59% to 72%) while predicting low, moderate, and high severity classes. Whereas GB model demonstrated better recall, i.e., completeness of positive predictions (56% to 75%) than RF (49% to 61%) for those classes. Closer investigations on topographic characteristics showed a varying relationship of severity patterns across different morphological landform classes. Landforms having lower slope curvatures or with unchanging slopes were more prone to severe burning than those landforms with higher slope curvatures. Our results provide insights into how topography influences potential bushfire severity risks and recommends purpose-specific choice of ML models.

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“…Fuel is another critical element for fire ignition, spread, and combustion. The fuel variables, such as land cover or land use, live fuel moisture content (LFMC) (Quan et al 2015;Quan et al 2017) and dead fuel moisture content (DFMC) (Resco de Dios et al 2015), fuel load (FL) (Quan, Li et al 2021), forestry type (FT), and tree species (TS) play important roles in wildfire probability prediction, since they have an important influence on fire behaviors and regimes (Cao et al 2017;Jaafari et al 2017;Luo et al 2019;Carrasco et al 2021;Gale et al 2021;Quan, Xie et al 2021). Among them, the live and dead fuel moisture contents are most commonly considered in wildfire probability modeling at present (Yebra et al 2013;Nolan, Boer et al 2020;Quan, Xie et al 2021) because the large-scale and dynamic monitoring of these variables is available, either from remote sensing data or meteorological data (Yebra et al 2008;Nolan et al 2016;Fan and He 2021;Quan, Yebra et al 2021).…”

Section: Introductionmentioning

confidence: 99%

Improving Wildfire Probability Modeling by Integrating Dynamic-Step Weather Variables over Northwestern Sichuan, China

Chen

Quan

et al. 2023

Int J Disaster Risk Sci

Self Cite

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Wildfire occurrence is attributed to the interaction of multiple factors including weather, fuel, topography, and human activities. Among them, weather variables, particularly the temporal characteristics of weather variables in a given period, are paramount in predicting the probability of wildfire occurrence. However, rainfall has a large influence on the temporal characteristics of weather variables if they are derived from a fixed period, introducing additional uncertainties in wildfire probability modeling. To solve the problem, this study employed the weather variables in continuous nonprecipitation days as the “dynamic-step” weather variables with which to improve wildfire probability modeling. Multisource data on weather, fuel, topography, infrastructure, and derived variables were used to model wildfire probability based on two machine learning methods—random forest (RF) and extreme gradient boosting (XGBoost). The results indicate that the accuracy of the wildfire probability models was improved by adding dynamic-step weather variables into the models. The variable importance analysis also verified the top contribution of these dynamic-step weather variables, indicating the effectiveness of the consideration of dynamic-step weather variables in wildfire probability modeling.

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Application of Landsat ETM+ and OLI Data for Foliage Fuel Load Monitoring Using Radiative Transfer Model and Machine Learning Method

Cited by 28 publications

References 91 publications

Estimation of Forest Canopy Fuel Moisture Content in Dali Prefecture by Combining Vegetation Indices and Canopy Radiative Transfer Models from MODIS Data

Estimation of Forest Canopy Fuel Moisture Content in Dali Prefecture by Combining Vegetation Indices and Canopy Radiative Transfer Models from MODIS Data

Characterizing Topographic Influences of Bushfire Severity Using Machine Learning Models: A Case Study in a Hilly Terrain of Victoria, Australia

Improving Wildfire Probability Modeling by Integrating Dynamic-Step Weather Variables over Northwestern Sichuan, China

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