Remote sensing data fusion as a tool for biomass prediction in extensive grasslands invaded by <i>L. polyphyllus</i>

Schulze‐Brüninghoff, Damian; Wachendorf, M.; Astor, Thomas

doi:10.1002/rse2.182

Cited by 19 publications

(13 citation statements)

References 37 publications

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“…Non‐destructive estimates of AGB are conventionally obtained from in situ measurements of attributes such as plant cover, height and stem diameters, using functions fitted to harvested biomass observations (Paul et al., 2016 ; Rudgers et al., 2019 ). Canopy volume, the product of height and cover, is often the strongest predictor of AGB for low‐stature plants like shrubs and herbs (Alonzo et al., 2020 ; Bendig et al., 2014 ; Cunliffe et al., 2020a ; Grüner et al., 2019 , 2020 , 2021 ; Huenneke et al., 2001 ; Kröhnert et al., 2018 ; Schulze‐Brüninghoff et al., 2020 ; Wijesingha et al., 2019 ). Remote sensing approaches have been widely used to extend the coverage of biomass predictions.…”

Section: Introductionmentioning

confidence: 99%

Global application of an unoccupied aerial vehicle photogrammetry protocol for predicting aboveground biomass in non‐forest ecosystems

Cunliffe

Anderson

Boschetti

et al. 2021

Remote Sens Ecol Conserv

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Section: Introductionmentioning

confidence: 99%

Global application of an unoccupied aerial vehicle photogrammetry protocol for predicting aboveground biomass in non‐forest ecosystems

Cunliffe

Anderson

Boschetti

et al. 2021

Remote Sens Ecol Conserv

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“…Results of this study utilizing machine learning methods to UAV images achieved F 1‐scores that are comparable to previous studies of plant segmentation (Elkind et al., 2019; Martins et al., 2021; Torres et al., 2020). Some studies implemented additional information such as digital surface models (DSMs) or multi‐spectral data to classify species to obtain similar or better F 1‐scores (Benjamin et al., 2021; Chabot et al., 2018; Durgan et al., 2020; Husson et al., 2016; Schulze‐Brüninghoff et al., 2021). However, retrieving DSMs might be difficult in kettle holes, for example, under windy conditions due to moving vegetation (Pätzig et al., 2020) Moreover, the application of multi‐spectral cameras makes the approach more expensive.…”

Section: Discussionmentioning

confidence: 99%

Identifying plant species in kettle holes using UAV images and deep learning techniques

Martins

Marcato

Pätzig

et al. 2022

Remote Sens Ecol Conserv

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The use of uncrewed aerial vehicle to map the environment increased significantly in the last decade enabling a finer assessment of the land cover. However, creating accurate maps of the environment is still a complex and costly task. Deep learning (DL) is a new generation of artificial neural network research that, combined with remote sensing techniques, allows a refined understanding of our environment and can help to solve challenging land cover mapping issues. This research focuses on the vegetation segmentation of kettle holes. Kettle holes are small, pond‐like, depressional wetlands. Quantifying the vegetation present in this environment is essential to assess the biodiversity and the health of the ecosystem. A machine learning workflow has been developed, integrating a superpixel segmentation algorithm to build a robust dataset, which is followed by a set of DL architectures to classify 10 plant classes present in kettle holes. The best architecture for this task was Xception, which achieved an average F1‐score of 85% in the segmentation of the species. The application of solely 318 samples per class enabled a successful mapping in the complex wetland environment, indicating an important direction for future health assessments in such landscapes.

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“…However, this approach is both timeconsuming and spatially constrained [5]. Owing to its high spatial, temporal, and spectral resolution, as well as its capacity for continuous, long-term scientific observations, remote sensing technology has become a widely employed tool for biomass estimation [10][11][12][13]. Broadly speaking, forest biomass estimation via remote sensing has evolved through three stages: (1) estimation solely based on optical, radar, or Light Detection and Ranging (LiDAR) data [14,15]; (2) effective incorporation of multiple types of satellite imagery, mitigating the limitations of solitary satellite imagery data [16]; (3) selection of optimal variables from multi-source satellite imagery and ancillary data [5], thereby enhancing model accuracy [12,17].…”

Section: Introductionmentioning

confidence: 99%

Comparison of Different Important Predictors and Models for Estimating Large-Scale Biomass of Rubber Plantations in Hainan Island, China

Wang

Gao

et al. 2023

Remote Sensing

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Rubber (Hevea brasiliensis Muell.) plantations are among the most critical agricultural ecosystems in tropical regions, playing a vital role in regional carbon balance. Accurate large-scale biomass estimation for these plantations remains a challenging task due to the severe signal saturation problem. Recent advances in remote sensing big data, cloud platforms, and machine learning have facilitated the precise acquisition of key physiological variables, such as stand age (A) and canopy height (H), which are critical parameters for biomass estimation but have been underutilized in prior studies. Using Hainan Island—the second-largest rubber planting base in China—as a case study, we integrated extensive ground surveys, maps of stand age and canopy height, remote sensing indicators (RSIs), and geographical and climate indicators (ECIs) to ascertain the optimal method for estimating rubber plantation biomass. We compared different inputs and estimation approaches (direct and indirect) using the random forest algorithm and analyzed the spatiotemporal characteristics of rubber plantation biomass on Hainan Island. The results indicated that the traditional model (RSIs + ECIs) had low accuracy and significant estimation bias (R2 = 0.24, RMSE = 38.36 mg/ha). The addition of either stand age or canopy height considerably enhance model accuracy (R2 = 0.77, RMSE ≈ 21.12 mg/ha). Moreover, incorporating the DBH obtained through indirect inversion yielded even greater predictive accuracy (R2 = 0.97, RMSE = 7.73 mg/ha), outperforming estimates derived from an allometric equation model input with the DBH (R2 = 0.67, RMSE = 25.43 mg/ha). However, augmenting the model with stand age, canopy height, or their combination based on RSIs, ECIs, and DBH only marginally improved the accuracy. Consequently, it is not recommended in scenarios with limited data and computing resources. Employing the optimal model, we generated biomass maps of rubber plantations on Hainan Island for 2016 and 2020, revealing that the spatiotemporal distribution pattern of the biomass is closely associated with the establishment year of the rubber plantations. While average biomass in a few areas has undergone slight decreases, total biomass has exhibited significant growth, reaching 5.46 × 107 mg by the end of 2020, underscoring its considerable value as a carbon sink.

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Remote sensing data fusion as a tool for biomass prediction in extensive grasslands invaded by L. polyphyllus

Cited by 19 publications

References 37 publications

Global application of an unoccupied aerial vehicle photogrammetry protocol for predicting aboveground biomass in non‐forest ecosystems

Global application of an unoccupied aerial vehicle photogrammetry protocol for predicting aboveground biomass in non‐forest ecosystems

Identifying plant species in kettle holes using UAV images and deep learning techniques

Comparison of Different Important Predictors and Models for Estimating Large-Scale Biomass of Rubber Plantations in Hainan Island, China

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