Predicting Fine Dead Fuel Load of Forest Floors Based on Image Euler Numbers

Zhang, Yunlin; Tian, Lingling

doi:10.3390/f15040726

Forests

2024

DOI: 10.3390/f15040726

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Predicting Fine Dead Fuel Load of Forest Floors Based on Image Euler Numbers

Yunlin Zhang,

Lingling Tian

Abstract: The fine dead fuel load on forest floors is the most critical classification feature in fuel description systems, affecting several parameters in the manifestation of wildland fires. An accurate determination of this fine dead fuel load contributes substantially to effective wildland fire prevention, monitoring, and suppression. This study investigated the viability of incorporating image Euler numbers into predictive models of fine dead fuel load via the taking photos method. Pinus massoniana needles and Quer… Show more

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2024

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Cited by 1 publication

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Use of airborne LiDAR to predict fine dead fuel load in Mediterranean forest stands of Southern Europe

Lin,

Giannico,

Lafortezza

et al. 2024

fire ecol

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Background Mediterranean forests are increasingly threatened by wildfires, with fuel load playing a crucial role in fire dynamics and behaviors. Accurate fuel load determination contributes substantially to the wildfire monitoring, management, and prevention. This study aimed to evaluate the effectiveness of airborne Light Detection and Ranging (LiDAR) data in estimating fine dead fuel load, focusing on the development of models using LiDAR-derived metrics to predict various categories of fine dead fuel load. The estimation of fine dead fuel load was performed by the integration of field data and airborne LiDAR data by applying multiple linear regression analysis. Model performance was evaluated by the coefficient of determination (R2), root mean squared error (RMSE), and mean absolute error (MAE). Results Through multiple linear regression models, the study explored the relationship between LiDAR-derived height and canopy cover metrics and different types of fine dead fuel load (1-h, 10-h, 100-h fuel loads, and litter). The accuracy of these models varied, with litter prediction showing the highest accuracy (R2 = 0.569, nRMSE = 0.158). In contrast, the 1-h fuel load prediction was the least accurate (R2 = 0.521, nRMSE = 0.168). The analysis highlighted the significance of specific LiDAR metrics in predicting different fuel loads, revealing a strong correlation between the vertical structure of vegetation and the accumulation of fine dead fuels. Conclusions The findings demonstrate the potential of airborne LiDAR data in accurately estimating fine dead fuel loads in Mediterranean forests. This capability is significant for enhancing wildfire management, including risk assessment and mitigation. The study underscores the relevance of LiDAR in environmental monitoring and forest management, particularly in regions prone to wildfires.

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Use of airborne LiDAR to predict fine dead fuel load in Mediterranean forest stands of Southern Europe

Lin,

Giannico,

Lafortezza

et al. 2024

fire ecol

View full text Add to dashboard Cite

show abstract

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Predicting Fine Dead Fuel Load of Forest Floors Based on Image Euler Numbers

Cited by 1 publication

References 29 publications

Use of airborne LiDAR to predict fine dead fuel load in Mediterranean forest stands of Southern Europe

Use of airborne LiDAR to predict fine dead fuel load in Mediterranean forest stands of Southern Europe

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