The Importance of Consistent Global Forest Aboveground Biomass Product Validation

Duncanson, Laura; Armston, John; Disney, Mathias; Avitabile, Valerio; Barbier, Nicolas; Calders, Kim; Carter, S.; Chave, Jérôme; Herold, Martin; Crowther, Thomas W.; Falkowski, Michael J.; Kellner, James R.; Labrière, Nicolas; Lucas, Richard; MacBean, Natasha; McRoberts, Ronald E.; Meyer, Victoria; Næsset, Erik; Nickeson, Jaime; Paul, Keryn I.; Phillips, Oliver L.; Réjou‐Méchain, Maxime; Román, M. O.; Roxburgh, Stephen H.; Saatchi, Sassan; Schepaschenko, Dmitry; Scipal, Klaus; Siqueira, Paul; Whitehurst, Amanda; Williams, Mathew

doi:10.1007/s10712-019-09538-8

Cited by 154 publications

(154 citation statements)

References 59 publications

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“…Maps and estimates of forest V and its changes are central to understand the carbon and water cycles, for assessing the climate change mitigation potential of forests and to quantify ecosystem services [1]. Several earth observation missions, such as Global Ecosystem Dynamics Investigation (GEDI), NASA-ISRO SAR Mission (NISAR), and BIOMASS, aim specifically at mapping forest AGB and will improve our ability to consistently map and estimate forest resources across the globe [2,3]. Still, all operational applications of remote sensing techniques for forest inventory require field observations for calibration of models and their validation [4].…”

Section: Introductionmentioning

confidence: 99%

Estimation of Forest Growing Stock Volume with UAV Laser Scanning Data: Can It Be Done without Field Data?

2020

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Laser scanning data from unmanned aerial vehicles (UAV-LS) offer new opportunities to estimate forest growing stock volume ( V ) exclusively based on the UAV-LS data. We propose a method to measure tree attributes and using these measurements to estimate V without the use of field data for calibration. The method consists of five steps: i) Using UAV-LS data, tree crowns are automatically identified and segmented wall-to-wall. ii) From all detected tree crowns, a sample is taken where diameter at breast height (DBH) can be recorded reliably as determined by visual assessment in the UAV-LS data. iii) Another sample of crowns is taken where tree species were identifiable from UAV image data. iv) DBH and tree species models are fit using the samples and applied to all detected tree crowns. v) Single tree volumes are predicted with existing allometric models using predicted species and DBH, and height directly obtained from UAV-LS. The method was applied to a Riegl-VUX data set with an average density of 1130 points m−2 and 3 cm orthomosaic acquired over an 8.8 ha managed boreal forest. The volumes of the identified trees were aggregated to estimate plot-, stand-, and forest-level volumes which were validated using 58 independently measured field plots. The root-mean-square deviance ( R M S D % ) decreased when increasing the spatial scale from the plot (32.2%) to stand (27.1%) and forest level (3.5%). The accuracy of the UAV-LS estimates varied given forest structure and was highest in open pine stands and lowest in dense birch or spruce stands. On the forest level, the estimates based on UAV-LS data were well within the 95% confidence interval of the intense field survey estimate, and both estimates had a similar precision. While the results are encouraging for further use of UAV-LS in the context of fully airborne forest inventories, future studies should confirm our findings in a variety of forest types and conditions.

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Section: Introductionmentioning

confidence: 99%

Estimation of Forest Growing Stock Volume with UAV Laser Scanning Data: Can It Be Done without Field Data?

2020

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“…This has greatly facilitated the use of remotely sensed data for forest monitoring across various spatial and temporal scales. At global and national levels, coarse resolution optical satellite imagery provides useful information for estimating forest cover [11,12] and biomass [13,14]. At the level of forest properties and stands, high-resolution three-dimensional data have proven particularly useful for forest inventory applications [15].…”

Section: Introductionmentioning

confidence: 99%

Classifications of Forest Change by Using Bitemporal Airborne Laser Scanner Data

et al. 2019

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Changes in forest areas have great impact on a range of ecosystem functions, and monitoring forest change across different spatial and temporal resolutions is a central task in forestry. At the spatial scales of municipalities, forest properties and stands, local inventories are carried out periodically to inform forest management, in which airborne laser scanner (ALS) data are often used to estimate forest attributes. As local forest inventories are repeated, the availability of bitemporal field and ALS data is increasing. The aim of this study was to assess the utility of bitemporal ALS data for classification of dominant height change, aboveground biomass change, forest disturbances, and forestry activities. We used data obtained from 558 field plots and four repeated ALS-based forest inventories in southeastern Norway, with temporal resolutions ranging from 11 to 15 years. We applied the k-nearest neighbor method for classification of: (i) increasing versus decreasing dominant height, (ii) increasing versus decreasing aboveground biomass, (iii) undisturbed versus disturbed forest, and (iv) forestry activities, namely untouched, partial harvest, and clearcut. Leave-one-out cross-validation revealed overall accuracies of 96%, 95%, 89%, and 88% across districts for the four change classifications, respectively. Thus, our results demonstrate that various changes in forest structure can be classified with high accuracy at plot level using data from repeated ALS-based forest inventories.

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“…Therefore, structural metrics of a globally spread large number of trees needs to be analyzed in analogy to the global efforts that have been done to construct the LES. To achieve such an ambition, a community effort will be needed to standardize TLS data collection protocols [in line with other current similar efforts, e.g., CEOS (Duncanson et al, 2019)], and establish a repository for reconstructed trees with associated metadata to ensure reproducibility. Challenges remain to accurately extract individual trees from scans of 3D forest point clouds and reconstruct tree architecture.…”

Section: Outlook and Conclusionmentioning

confidence: 99%

Time for a Plant Structural Economics Spectrum

Verbeeck

Bauters

Jackson

et al. 2019

Front. For. Glob. Change

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We argue that tree and crown structural diversity can and should be integrated in the whole-plant economics spectrum. Ecologists have found that certain functional trait combinations have been more viable than others during evolution, generating a trait trade-off continuum which can be summarized along a few axes of variation, such as the "worldwide leaf economics spectrum" and the "wood economics spectrum." However, for woody plants the crown structural diversity should be included as well in the recently introduced "global spectrum of plant form and function," which now merely focusses on plant height as structural factor. The recent revolution in terrestrial laser scanning (TLS) unlocks the possibility to describe the three dimensional structure of trees quantitatively with unprecedented detail. We demonstrate that based on TLS data, a multidimensional structural trait space can be constructed, which can be decomposed into a few descriptive axes or spectra. We conclude that the time has come to develop a "structural economics spectrum" for woody plants based on structural trait data across the globe. We make suggestions as to what structural features might lie on this spectrum and how these might help improve our understanding of tree form-function relationships.

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The Importance of Consistent Global Forest Aboveground Biomass Product Validation

Cited by 154 publications

References 59 publications

Estimation of Forest Growing Stock Volume with UAV Laser Scanning Data: Can It Be Done without Field Data?

Estimation of Forest Growing Stock Volume with UAV Laser Scanning Data: Can It Be Done without Field Data?

Classifications of Forest Change by Using Bitemporal Airborne Laser Scanner Data

Time for a Plant Structural Economics Spectrum

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