Evaluating Site-Specific and Generic Spatial Models of Aboveground Forest Biomass Based on Landsat Time-Series and LiDAR Strip Samples in the Eastern USA

Deo, Ram K.; Russell, Matthew B.; Domke, Grant M.; Andersen, Hans Erik; Cohen, Warren B.; Woodall, Christopher W.

doi:10.3390/rs9060598

Cited by 43 publications

(35 citation statements)

References 77 publications

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“…Among the selected variables from both LiDAR and Landsat data, LiDAR metrics were much more influential to stand basal area and associated AGB than Landsat variables. This finding is consistent with previous studies (Deo et al 2017a(Deo et al , 2017b. Nevertheless, we found that Landsat variables alone can also be used to replace stand basal area to predict AGB in the study region although with higher RMSE (9.34-12 Mg ha −1 ).…”

Section: Discussionsupporting

confidence: 93%

“…The average width of the strips was about 1.2 km. The LiDAR datasets were summarized to obtain the grid metrics for canopy cover and vertical strata density as defined in Deo et al (2017aDeo et al ( , 2017b. In addition, the Landsat time-series data were acquired by Landsat-5 Thematic Mapper (TM) and Landsat-8 Operational Land Imager (OLI) sensors at the peak of the growing seasons (July-September) from 1984-2015.…”

Section: Lidar and Landsat Datamentioning

confidence: 99%

“…Heath et al 2011, Woodall et al 2015a. Recent work has highlighted that the accuracy and precision of AGB dynamics over a range of spatial scales could be further improved by incorporating vegetation indices as predictors derived from remotely sensed data that are temporally consistent and spatially continuous (Deo et al 2017a). Providing spatially continuous and temporally consistent estimates of AGB dynamics in forests at large-scales is crucial for evaluating existing land use policies and land management practices intended to help mitigate GHG emissions (Woodall et al 2015b, Deo et al 2017b.…”

Section: Introductionmentioning

confidence: 99%

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Using matrix models to estimate aboveground forest biomass dynamics in the eastern USA through various combinations of LiDAR, Landsat, and forest inventory data

Wörns

Domke

D’Amato

et al. 2018

Environ. Res. Lett.

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The ability to harmonize data sources with varying temporal, spatial, and ecosystem measurements (e.g. forest structure to soil organic carbon) for creation of terrestrial carbon baselines is paramount to refining the monitoring of terrestrial carbon stocks and stock changes. In this study, we developed and examined the short-(5 years) and long-term (30 years) performance of matrix models for incorporating light detection and ranging (LiDAR) strip samples and time-series Landsat surface reflectance high-level data products, with field inventory measurements to predict aboveground biomass (AGB) dynamics for study sites across the eastern USA-Minnesota (MN), Maine (ME), Pennsylvania-New Jersey (PANJ) and South Carolina (SC). The rows and columns of the matrix were stand density (i.e. number of trees per unit area) sorted by inventory plot and by species group and diameter class. Through model comparisons in the short-term, we found that average stand basal area (B) predicted by three matrix models all fell within the 95% confidence interval of observed values. The three matrix models were based on (i) only field inventory variables (inventory), (ii) LiDAR and Landsat-derived metrics combined with field inventory variables (LiDAR+Landsat+inventory), and (iii) only Landsat-derived metrics combined with field inventory variables (Landsat+inventory), respectively. In the long term, predicted AGB using LiDAR+Landsat+inventory and Land-sat+inventory variables had similar AGB patterns (differences within 7.2 Mg ha −1 ) to those predicted by matrix models with only inventory variables from 2015-2045. When considering uncertainty derived from fuzzy sets all three matrix models had similar AGBs (differences within 7.6 Mg ha −1 ) by the year 2045. Therefore, the use of matrix models enabled various combinations of LiDAR, Landsat, and field data, especially Landsat data, to estimate large-scale AGB dynamics (i.e. central component of carbon stock monitoring) without loss of accuracy from only using variables from forest inventories. These findings suggest that the use of Landsat data alone incorporating elevation (E), plot slope (S) and aspect (A), and site productivity (C) could produce suitable estimation of AGB dynamics (ranging from 67.1-105.5 Mg ha −1 in 2045) to actual AGB dynamics using matrix models. Such a framework may afford refined monitoring and estimation of terrestrial carbon stocks and stock changes from spatially explicit to spatially explicit and spatially continuous estimates and also provide temporal flexibility and continuity with the Landsat time series.

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Section: Discussionsupporting

confidence: 93%

Section: Lidar and Landsat Datamentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Using matrix models to estimate aboveground forest biomass dynamics in the eastern USA through various combinations of LiDAR, Landsat, and forest inventory data

Wörns

Domke

D’Amato

et al. 2018

Environ. Res. Lett.

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“…Airborne laser scanning (ALS) is a widely used LiDAR technology in forestry, which has a unique advantage in 3D terrain and forest height detection. It can quickly and accurately obtain a digital surface model (DSM) and forest height information for forested land [4,5]. According to the statistics, single-tree detection algorithms that use active RS data, such as ALS, have grown rapidly in recent years, accounting for 80% of the total increase in RS area, at the same time, those algorithms using passive data or a fusion of passive and active data accounts for 8% and 12% respectively [6].…”

Section: Introductionmentioning

confidence: 99%

Automatic Detection of Single Trees in Airborne Laser Scanning Data through Gradient Orientation Clustering

Dong

Zhou

Sibin

et al. 2018

Forests

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Currently, existing methods for single-tree detection based on airborne laser scanning (ALS) data usually require some thresholds and parameters to be set manually. Manually setting threshold or parameters is laborious and time-consuming, and for dense forests, the high commission and omission rate make most existing single-tree detection techniques inefficient. As a solution to these problems, this paper proposed an automatic single-tree detection method in ALS data through gradient orientation clustering (GOC). In this method, the rasterized Canopy Height Model (CHM) was derived from ALS data using surface interpolation. Then, potential trees were assumed as approximate conical shapes and extracted based on the GOC. Finally, trees were identified from the potential trees based on the compactness of the crown shape. This method used the gradient orientation information of rasterized CHM, thus increasing the generalization of single-tree detection method. In order to verify the validity and practicability of the proposed method, twelve 1256 m 2 circular study plots of different forest types were selected from the benchmark dataset (NEWFOR), and the results from nine different methods were presented and compared for these study plots. Among nine methods, the proposed method had the highest root mean square matching score (RMS_M = 43). Moreover, the proposed method had excellent detection (M > 47) in both single-layer coniferous and single-layered mixed stands.

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“…As the principal part of terrestrial ecosystems, forest ecosystems hold approximately 80% of the terrestrial aboveground and below-ground biomass, and play very important roles in the global carbon cycle and climate change [1][2][3]. Since the temperate and boreal forests play a crucial role as atmospheric CO2 sinks, more attention has been paid to climatic warming in mid-and high-latitudes…”

Section: Introductionmentioning

confidence: 99%

Estimation of Forest Biomass Patterns across Northeast China Based on Allometric Scale Relationship

Cao

Zhou

et al. 2017

Forests

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This study develops a modeling framework for utilizing the large footprint LiDAR waveform data from the Geoscience Laser Altimeter System (GLAS) onboard NASA's Ice, Cloud, and Land Elevation Satellite (ICESat), Moderate Resolution Imaging Spectro-Radiometer (MODIS) imagery, meteorological data, and forest measurements for monitoring stocks of total biomass (including aboveground biomass and root biomass). The forest tree height models were separately used according to the artificial neural network (ANN) and the allometric scaling and resource limitation (ASRL) tree height models which can both combine the climate data and satellite data to predict forest tree heights. Based on the allometric approach, the forest aboveground biomass model was developed from the field measured aboveground biomass data and the tree heights derived from two tree height models. Then, the root biomass should scale with the aboveground biomass. To investigate whether this approach is efficient for estimating forest total biomass, we used Northeast China as the object of study. Our results generally proved that the method proposed in this study could be meaningful for forest total biomass estimation (R 2 = 0.699, RMSE = 55.86).

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Evaluating Site-Specific and Generic Spatial Models of Aboveground Forest Biomass Based on Landsat Time-Series and LiDAR Strip Samples in the Eastern USA

Cited by 43 publications

References 77 publications

Using matrix models to estimate aboveground forest biomass dynamics in the eastern USA through various combinations of LiDAR, Landsat, and forest inventory data

Using matrix models to estimate aboveground forest biomass dynamics in the eastern USA through various combinations of LiDAR, Landsat, and forest inventory data

Automatic Detection of Single Trees in Airborne Laser Scanning Data through Gradient Orientation Clustering

Estimation of Forest Biomass Patterns across Northeast China Based on Allometric Scale Relationship

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