Evaluation of Riparian Tree Cover and Shading in the Chauga River Watershed Using LiDAR and Deep Learning Land Cover Classification

Bolick, Madeleine M.; Post, Christopher J.; Mikhailova, Elena A.; Zurqani, Hamdi A.; Grunwald, Andrew P.; Saldo, Elizabeth A.

doi:10.3390/rs13204172

Cited by 7 publications

(2 citation statements)

References 52 publications

(66 reference statements)

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“…However, there are substantial reductions in solar radiation in small streams (due to riparian shading) [89] or large rivers (due to water depth) [85]. Although canopy cover can reduce solar radiation exposures of rivers [90], especially in forest-dominated watersheds, the water column removal in shallow streams might be underestimated without considering solar radiation [85]. Interaction with sediments, suspended particles and organic debris can result in persistence of fecal-borne bacteria [84].…”

Section: Discussionmentioning

confidence: 99%

Removal of Fecal Indicator Bacteria by River Networks

Huang

Wollheim

Jones

2022

Water

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Fecal contamination is a significant source of water quality impairment globally. Aquatic ecosystems can provide an important ecosystem service of fecal contamination removal. Understanding the processes that regulate the removal of fecal contamination among river networks across flow conditions is critical. We applied a river network model, the Framework for Aquatic Modeling in the Earth System (FrAMES-Ecoli), to quantify removal of fecal indicator bacteria by river networks across flow conditions during summers in a series of New England watersheds of different characteristics. FrAMES-Ecoli simulates sources, transport, and riverine removal of Escherichia coli (E. coli). Aquatic E. coli removal was simulated in both the water column and the hyporheic zone, and is a function of hydraulic conditions, flow exchange rates with the hyporheic zone, and die-off in each compartment. We found that, at the river network scale during summers, removal by river networks can be high (19–99%) with variability controlled by hydrologic conditions, watershed size, and distribution of sources in the watershed. Hydrology controls much of the variability, with 68–99% of network scale inputs removed under base flow conditions and 19–85% removed during storm events. Removal by the water column alone could not explain the observed pattern in E. coli, suggesting that processes such as hyporheic removal must be considered. These results suggest that river network removal of fecal indicator bacteria should be taken into consideration in managing fecal contamination at critical downstream receiving waters.

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Section: Discussionmentioning

confidence: 99%

Removal of Fecal Indicator Bacteria by River Networks

Huang

Wollheim

Jones

2022

Water

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“…MLAs generally exploit multispectral or hyperspectral data as input features, and attempt to predict some riparian vegetation classes. Scholars generally exploit supervised MLAs, which implies having a ground truth to be exploited for evaluating the algorithms [8]- [11]. Unsupervised MLAs are less studied in riparian vegetation mapping as they are considered less accurate than supervised approaches [12].…”

Section: Introductionmentioning

confidence: 99%

Remote Sensing and Machine Learning for Riparian Vegetation Detection and Classification

Fiorentini,

Bacco,

Ferrari

et al. 2023

2023 IEEE International Workshop on Metrology for Agriculture and Forestry (MetroAgriFor)

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Precise and reliable identification of riparian vegetation along rivers is of paramount importance for managing bodies, enabling them to accurately plan key duties, such as the design of river maintenance interventions. Nonetheless, manual mapping is significantly expensive in terms of time and human costs, especially when authorities have to manage extensive river networks. Accordingly, in the present paper, we propose a methodology for detecting and automatically classifying the riparian vegetation of urban rivers. Specifically, the calibration of an unsupervised (Isodata Clustering) and a supervised (Random Forest) machine learning algorithm (MLA) is carried out for the classification of the riparian vegetation detected in aerial orthoimages with a resolution of 1 meter. Riparian vegetation is classified using Normalized Difference Vegetation Index (NDVI) features. In the framework of this research, the Isodata Clustering slightly outperforms the Random Forest, achieving a higher level of predictive performance and reliability throughout all the computed performance metrics. Moreover, being unsupervised, it does not require ground truth information, which makes it particularly competitive in terms of annotation costs when compared with supervised algorithms, and definitely appropriate in case of limited resources. We encourage river authorities to use MLA-based tools, such as the ones we propose in this work, for mapping riparian vegetation, since they can bring relevant benefits, such as limited implementation costs, easy calibration, fast training, and adequate reliability.

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Conclusions and Recommendations for Environmental Applications of Remote Sensing and GIS in Libya

Zurqani

2022

Environmental Applications of Remote Sensing and GIS in Libya

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Evaluation of Riparian Tree Cover and Shading in the Chauga River Watershed Using LiDAR and Deep Learning Land Cover Classification

Cited by 7 publications

References 52 publications

Removal of Fecal Indicator Bacteria by River Networks

Removal of Fecal Indicator Bacteria by River Networks

Remote Sensing and Machine Learning for Riparian Vegetation Detection and Classification

Conclusions and Recommendations for Environmental Applications of Remote Sensing and GIS in Libya

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