Abstract
Benthic habitats are structurally complex and ecologically diverse ecosystems that are severely vulnerable to human stressors. Consequently, marine habitats must be mapped and monitored to provide the information necessary to understand ecological processes and lead management actions. In this study, we propose a semiautomated framework for the detection and mapping of benthic habitats and seagrass species using convolutional neural networks (CNNs). Benthic habitat field data from a geo-located towed camera and high-resolution satellite images were integrated to evaluate the proposed framework. Features extracted from pre-trained CNNs and a “bagging of features” (BOF) algorithm was used for benthic habitat and seagrass species detection. Furthermore, the resultant correctly detected images were used as ground truth samples for training and validating CNNs with simple architectures. These CNNs were evaluated for their accuracy in benthic habitat and seagrass species mapping using high-resolution satellite images. Two study areas, Shiraho and Fukido (located on Ishigaki Island, Japan), were used to evaluate the proposed model because seven benthic habitats were classified in the Shiraho area and four seagrass species were mapped in Fukido cove. Analysis showed that the overall accuracy of benthic habitat detection in Shiraho and seagrass species detection in Fukido was 91.5% (7 classes) and 90.4% (4 species), respectively, while the overall accuracy of benthic habitat and seagrass mapping in Shiraho and Fukido was 89.9% and 91.2%, respectively.
Highlights
High-resolution underwater video systems have enabled scientific discoveries of the seafloor related to marine studies, environmental management, and species monitoring
The main achievements described here aRremeosteuSmensm. 2a02r0i,z1e2d, xas follows: (i) We combined convolutional neural networks (CNNs) attributes, i.e., image features extra4ctoef d17 from pre-trained CNNs, and bagging of features” (BOF) attributes to exploit their diversity; (ii) we demonstrated that our proposed methboednothuitcphearbfoitramt ms saipnpgilnegCuNsiNngaCnNd NBOs wF iatlhgsoirmitphlme asruchsiintegcttuwreosd
Benthic habitats and seagrasses were detected by support vector machines (SVMs) [39,40] classifier using attributes extracted from pre-trained CNNs and a BOF [41,42] approach
Summary
High-resolution underwater video systems have enabled scientific discoveries of the seafloor related to marine studies, environmental management, and species monitoring. Towed underwater video cameras play an important role in detecting benthic habitats [1,2] by facilitating detailed observations and field sampling of unexplored marine ecosystems. Towed video cameras are low cost, have fast processing, and are environmentally sustainable, i.e., they do not harm the environment. These video systems produce low light, increased turbidity, and images with high noise, which all pose challenges for underwater video analysis. The images produced by towed video cameras usually have low contrast and low saturation; these often provide insufficient information for the recognition and discrimination of species. The captured images often consist of an assemblage of benthic habitats with irregular shapes and sizes [3]
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