LIDAR-Based Forest Biomass Remote Sensing: A Review of Metrics, Methods, and Assessment Criteria for the Selection of Allometric Equations

The increasing level of atmospheric carbon dioxide and its effects on our climate system has become a global environment issue. The forest ecosystem is essential for the stability of carbon in the atmosphere as it operates as a carbon sink and provides a habitat for numerous species. Therefore, our...

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Bibliographic Details
Published in:Forests 2023-10, Vol.14 (10), p.2095
Main Authors: Borsah, Abraham Aidoo, Nazeer, Majid, Wong, Man Sing
Format: Article
Language:English
Subjects:
assessment
Atmospheric models
Biodiversity
Biomass
Carbon dioxide
Carbon sinks
Climate change
Climate effects
Climate system
Criteria
Data collection
Earth
Environmental aspects
Equations
Forest biomass
Forest ecosystems
forest structure
Forests
Forests and forestry
Hong Kong
Lasers
LIDAR
Mathematical models
Measurement
Methods
metrics
Optical radar
Remote sensing
Root-mean-square errors
Sensors
Spatial variations
Structural members
Technology
Terrestrial ecosystems
Uncertainty analysis
Vegetation
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Summary:The increasing level of atmospheric carbon dioxide and its effects on our climate system has become a global environment issue. The forest ecosystem is essential for the stability of carbon in the atmosphere as it operates as a carbon sink and provides a habitat for numerous species. Therefore, our understanding of the structural elements of the forest ecosystem is vital for the estimation of forest biomass or terrestrial carbon stocks. Over the last two decades, light detection and ranging (LIDAR) technology has significantly revolutionized our understanding of forest structures and enhanced our ability to monitor forest biomass. This paper presents a review of metrics for forest biomass estimation, outlines metrics selection methods for biomass modeling, and addresses various assessment criteria for the selection of allometric equations for the aboveground forest biomass estimations, using LIDAR data. After examining one hundred publications written by different authors between 1999 and 2023, it was observed that LIDAR technology has become a dominant data collection tool for aboveground biomass estimation with most studies focusing on the use of airborne LIDAR data for the plot-level analysis on a local scale. Parametric-based models dominated in most studies with coefficient of determination (R2) and root mean square error (RMSE) as assessment criteria. In addition, mean top canopy height (MCH) and quadratic mean height (QMH) were reported as strong predictors for aboveground biomass (AGB) estimation. Pixel-based uncertainty analysis was found to be a reliable method for assessing spatial variations in uncertainties.
ISSN:1999-4907
1999-4907
DOI:10.3390/f14102095