Abstract
Intertidal habitats like oyster reefs and salt marshes provide vital ecosystem services including shoreline erosion control, habitat provision, and water filtration. However, these systems face significant global change as a result of a combination of anthropogenic stressors like coastal development and environmental stressors such as sea-level rise and disease. Traditional intertidal habitat monitoring techniques are cost and time-intensive, thus limiting how frequently resources are mapped in a way that is often insufficient to make informed management decisions. Unoccupied aircraft systems (UASs) have demonstrated the potential to mitigate these costs as they provide a platform to rapidly, safely, and inexpensively collect data in coastal areas. In this study, a UAS was used to survey intertidal habitats along the Gulf of Mexico coastline in Florida, USA. The structure from motion photogrammetry techniques were used to generate an orthomosaic and a digital surface model from the UAS imagery. These products were used in a geographic object-based image analysis (GEOBIA) workflow to classify mudflat, salt marsh, and oyster reef habitats. GEOBIA allows for a more informed classification than traditional techniques by providing textural and geometric context to habitat covers. We developed a ruleset to allow for a repeatable workflow, further decreasing the temporal cost of monitoring. The classification produced an overall accuracy of 79% in classifying habitats in a coastal environment with little spectral and textural separability, indicating that GEOBIA can differentiate intertidal habitats. This method allows for effective monitoring that can inform management and restoration efforts.
Highlights
Salt marshes and oyster reefs are ecologically significant estuarine habitats that face significant changes due to environmental and anthropogenic stressors
Developing an expedient workflow to monitor coastal environments is essential as stressors continue to alter coastal systems
As we continue to extract and divert water resources, estuarine systems that are reliant on freshwater inflow are of particular concern
Summary
Salt marshes and oyster reefs are ecologically significant estuarine habitats that face significant changes due to environmental and anthropogenic stressors. Oyster reefs are facing global decline as a result of stressors such as diseases, overharvest, coastal development, and alterations to hydrological flows caused by active water management inland [1]. Together, these stressors have caused an estimated 85% decline worldwide in oyster reef coverage over the last 130 years [2]. Ssienccteioonffoshf ocroearsetleifnseperosttiemctaitnesdhoareneotnleoss,sthoefir6d6%ecliinneowysiltlelrikreeleyf parreecaipsiitnactee 1fu98rt2h,ewr idthecalnin8e8s%innsheot rloes[s1o2]f.oAffdshdoitrieonreaellfys,[o1y].sSteinr cheaorvffesshtoirnetrheeefrsegpiroontehcatsininshcroeraesoendessi,gtnhiefiircadnetclylinine wfisihllinligkeelffyoprtreacnipditlaatnedfiunrgtshe[1r3d].ecTlhineesse itnresnhdorsear[1e2l]i.keAlyddtoiticoonnatlilnyu, eo,ygsitverenhathrvatesotthinerthneearrebgyioonyshtaesr ifinschreeraiseesdhsaivgenicfoicllaanptslyedin(sfeiesh[i1n4g]).effort and landings [13] These trends are likely to continue, given that other nearby oyster fisheries have collapsed (see [14])
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
