Abstract
Despite the abundance of research on coral reef change detection, few studies have been conducted to assess the spatial generalization principles of a live coral cover classifier trained using remote sensing data from multiple locations. The aim of this study is to develop a machine learning classifier for coral dominated benthic cover-type class (CDBCTC) based on ground truth observations and Landsat images, evaluate the performance of this classifier when tested against new data, then deploy the classifier to perform CDBCTC change analysis of multiple locations. The proposed framework includes image calibration, support vector machine (SVM) training and tuning, statistical assessment of model accuracy, and temporal pixel-based image differencing. Validation of the methodology was performed by cross-validation and train/test split using ground truth observations of benthic cover from four different reefs. These four locations (Palmyra Atoll, Kingman Reef, Baker Island Atoll, and Howland Island) as well as two additional locations (Kiritimati Island and Tabuaeran Island) were then evaluated for CDBCTC change detection. The in-situ training accuracy against ground truth observations for Palmyra Atoll, Kingman Reef, Baker Island Atoll, and Howland Island were 87.9%, 85.7%, 69.2%, and 82.1% respectively. The classifier attained generalized accuracy scores of 78.8%, 81.0%, 65.4%, and 67.9% for the respective locations when trained using ground truth observations from neighboring reefs and tested against the local ground truth observations of each reef. The classifier was trained using the consolidated ground truth data of all four sites and attained a cross-validated accuracy of 75.3%. The CDBCTC change detection analysis showed a decrease in CDBCTC of 32% at Palmyra Atoll, 25% at Kingman Reef, 40% at Baker Island Atoll, 25% at Howland Island, 35% at Tabuaeran Island, and 43% at Kiritimati Island. This research establishes a methodology for developing a robust classifier and the associated Controlled Parameter Cross-Validation (CPCV) process for evaluating how well the model will generalize to new data. It is an important step for improving the scientific understanding of temporal change within coral reefs around the globe.
Highlights
Coral reefs are among the most critical ecosystems in the world due to the role that they play in maintaining biodiversity and sustaining the lifecycle of so many marine species
The depth invariant indices (DII) values represent the features of the support vector machine (SVM) model and the corresponding observed benthic cover type the response
This was achieved by building a classifier for each of four locations (Palmyra Atoll, Kingman Reef, Baker Island Atoll, and Howland Island), applying the classifier to the initial state image and final state image, conducting a per-pixel change detection analysis
Summary
Coral reefs are among the most critical ecosystems in the world due to the role that they play in maintaining biodiversity and sustaining the lifecycle of so many marine species. It has been shown that classifiers based on higher resolution platforms typically attain a greater degree of accuracy, often by more than 10%, than lower resolution satellites [22] This is due to the reduced within pixel mixing of benthic cover types when attempting to classify highly heterogeneous ecosystems such as coral reefs [23]. The recent advancements in satellite technology have allowed high-resolution imagery to be readily available from multiple platforms While these platforms show great promise for analyzing the state of benthic habitats currently and in the recent past, they lack the history for a longer-term perspective on change. The quality of the data provided by missions has been proven to be appropriate for temporal analysis [30,31,32,33,34,35,36,37,38,39]
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