Assessing the effects of burn severity on post-fire tree structures using the fused drone and mobile laser scanning point clouds

Qi, Yangqian; Coops, Nicholas C.; Daniels, Lori D.; Butson, Christopher R.

doi:10.3389/fenvs.2022.949442

Cited by 7 publications

(5 citation statements)

References 107 publications

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“…Due to the higher surface fuel density and lower upper crown density, Chinese fir and mixed coniferous-broadleaved forests may have a higher probability of surface fires, consistent with previous research indicating that these stands possess highly flammable loads [58]. Furthermore, the ladder fuel density in Chinese fir and mixed coniferous-broadleaved forests is also higher, potentially making crown fires more likely [15,69,70]. This study emphasizes the need for pruning excess branches and increasing CBH in fuel management in Chinese subtropical forests to reduce contact with surface fuels [71,72].…”

Section: Conclusion and Management Implicationssupporting

confidence: 83%

Revealing Three-Dimensional Variations in Fuel Structures in Subtropical Forests through Backpack Laser Scanning

Kang,

Lin,

Huang

et al. 2024

Forests

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Wildfire hazard is a prominent issue in subtropical forests as climate change and extreme drought events increase in frequency. Stand-level fuel load and forest structure are determinants of forest fire occurrence and spread. However, current fuel management often lacks detailed vertical fuel distribution, limiting accurate fire risk assessment and effective fuel policy implementation. In this study, backpack laser scanning (BLS) is used to estimate several 3D structural parameters, including canopy height, crown base height, canopy volume, stand density, vegetation area index (VAI), and vegetation coverage, to characterize the fuel structure characteristics and vertical density distribution variation in different stands of subtropical forests in China. Through standard measurement using BLS point cloud data, we found that canopy height, crown base height, stand density, and VAI in the lower and middle-height strata differed significantly among stand types. Compared to vegetation coverage, the LiDAR-derived VAI can better show significant stratified changes in fuel density in the vertical direction among stand types. Among stand types, conifer-broadleaf mixed forest and C. lanceolata had a higher VAI in surface strata than other stand types, while P. massoniana and conifer-broadleaf mixed forests were particularly unique in having a higher VAI in the lower and middle-height strata, corresponding to the higher surface fuel and ladder fuel in the stand, respectively. To provide more informative support for forest fuel management, BLS LiDAR data combined with other remote sensing data were advocated to facilitate the visualization of fuel density distribution and the development of fire risk assessment.

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Section: Conclusion and Management Implicationssupporting

confidence: 83%

Revealing Three-Dimensional Variations in Fuel Structures in Subtropical Forests through Backpack Laser Scanning

Kang,

Lin,

Huang

et al. 2024

Forests

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“…Similar data fusion studies also predicted canopy fuel variables, such as canopy fuel load (kg/ m 2 ), and surface fuel layers (including coarse woody debris biomass) with adjusted R 2 ranging between 0.55-0.94 [166]. At the ITA scale, post-fire changes in DBH and biomass can be estimated by fusing MLS data with ULS/ALS, where the below-canopy measurements are enabled by the MLS data [162]. However, a fusion of ALS and TLS data for ITA metrics was recently documented to offer no particular advantage over either sensor used alone [169].…”

Section: Fuel Loadmentioning

confidence: 83%

“…6) Other: 9.1% of the papers [148][149][150][151][152][153][154][155][156][157][158][159][160] include a variety of applications, such as mapping the pigment distribution and quantifying taxonomic, functional, and phylogenetic diversity, tree age estimation etc. 7) Fuel load: 6.3% of the papers [161][162][163][164][165][166][167][168][169] include applications that deal with fuel load and forest fire modeling.…”

Section: Applicationsmentioning

confidence: 99%

“…The raw datasets can be fused using ground control points (GCPs) or by identifying similar features in the datasets [74,100] using the same coordinate system acquired through GNSS or total stations. Other studies [26,112,162] used manual co-registration by identifying similar features such as the tallest tree, trees with large crowns, or tree locations. These features were used to guide the manual shifting process and to correctly co-register the two datasets.…”

Section: Data-level Fusionmentioning

confidence: 99%

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LiDAR Data Fusion to Improve Forest Attribute Estimates: A Review

Balestra,

Marselis,

Sankey

et al. 2024

Curr. For. Rep.

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Purpose of the Review Many LiDAR remote sensing studies over the past decade promised data fusion as a potential avenue to increase accuracy, spatial-temporal resolution, and information extraction in the final data products. Here, we performed a structured literature review to analyze relevant studies on these topics published in the last decade and the main motivations and applications for fusion, and the methods used. We discuss the findings with a panel of experts and report important lessons, main challenges, and future directions. Recent Findings LiDAR fusion with other datasets, including multispectral, hyperspectral, and radar, is found to be useful for a variety of applications in the literature, both at individual tree level and at area level, for tree/crown segmentation, aboveground biomass assessments, canopy height, tree species identification, structural parameters, and fuel load assessments etc. In most cases, gains are achieved in improving the accuracy (e.g. better tree species classifications), and spatial-temporal resolution (e.g. for canopy height). However, questions remain regarding whether the marginal improvements reported in a range of studies are worth the extra investment, specifically from an operational point of view. We also provide a clear definition of “data fusion” to inform the scientific community on data fusion, combination, and integration. Summary This review provides a positive outlook for LiDAR fusion applications in the decade to come, while raising questions about the trade-off between benefits versus the time and effort needed for collecting and combining multiple datasets.

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“…Although methods have been developed to use TLS as an operational fuel hazard observation technology [104], wall-to-wall assessments over large areas are not feasible. In this sense, future research in fire severity behavior should address the use of mobile laser scanning (MLS), a new remote sensing technique that has not much been considered in forestry applications [105] and wildfire science [106].…”

Section: Discussionmentioning

confidence: 99%

Using Pre-Fire High Point Cloud Density LiDAR Data to Predict Fire Severity in Central Portugal

Fernández‐Guisuraga

Fernandes

2023

Remote Sensing

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The wall-to-wall prediction of fuel structural characteristics conducive to high fire severity is essential to provide integrated insights for implementing pre-fire management strategies designed to mitigate the most harmful ecological effects of fire in fire-prone plant communities. Here, we evaluate the potential of high point cloud density LiDAR data from the Portuguese áGiLTerFoRus project to characterize pre-fire surface and canopy fuel structure and predict wildfire severity. The study area corresponds to a pilot LiDAR flight area of around 21,000 ha in central Portugal intersected by a mixed-severity wildfire that occurred one month after the LiDAR survey. Fire severity was assessed through the differenced Normalized Burn Ratio (dNBR) index computed from pre- and post-fire Sentinel-2A Level 2A scenes. In addition to continuous data, fire severity was also categorized (low or high) using appropriate dNBR thresholds for the plant communities in the study area. We computed several metrics related to the pre-fire distribution of surface and canopy fuels strata with a point cloud mean density of 10.9 m−2. The Random Forest (RF) algorithm was used to evaluate the capacity of the set of pre-fire LiDAR metrics to predict continuous and categorized fire severity. The accuracy of RF regression and classification model for continuous and categorized fire severity data, respectively, was remarkably high (pseudo-R2 = 0.57 and overall accuracy = 81%) considering that we only focused on variables related to fuel structure and loading. The pre-fire fuel metrics with the highest contribution to RF models were proxies for horizontal fuel continuity (fractional cover metric) and the distribution of fuel loads and canopy openness up to a 10 m height (density metrics), indicating increased fire severity with higher surface fuel load and higher horizontal and vertical fuel continuity. Results evidence that the technical specifications of LiDAR acquisitions framed within the áGiLTerFoRus project enable accurate fire severity predictions through point cloud data with high density.

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Assessing the effects of burn severity on post-fire tree structures using the fused drone and mobile laser scanning point clouds

Cited by 7 publications

References 107 publications

Revealing Three-Dimensional Variations in Fuel Structures in Subtropical Forests through Backpack Laser Scanning

Revealing Three-Dimensional Variations in Fuel Structures in Subtropical Forests through Backpack Laser Scanning

LiDAR Data Fusion to Improve Forest Attribute Estimates: A Review

Using Pre-Fire High Point Cloud Density LiDAR Data to Predict Fire Severity in Central Portugal

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