Abstract
Coastal ecosystems are critically affected by seagrass, both economically and ecologically. However, reliable seagrass distribution information is lacking in nearly all parts of the world because of the excessive costs associated with its assessment. In this paper, we develop two deep learning models for automatic seagrass distribution quantification based on 8-band satellite imagery. Specifically, we implemented a deep capsule network (DCN) and a deep convolutional neural network (CNN) to assess seagrass distribution through regression. The DCN model first determines whether seagrass is presented in the image through classification. Second, if seagrass is presented in the image, it quantifies the seagrass through regression. During training, the regression and classification modules are jointly optimized to achieve end-to-end learning. The CNN model is strictly trained for regression in seagrass and non-seagrass patches. In addition, we propose a transfer learning approach to transfer knowledge in the trained deep models at one location to perform seagrass quantification at a different location. We evaluate the proposed methods in three WorldView-2 satellite images taken from the coastal area in Florida. Experimental results show that the proposed deep DCN and CNN models performed similarly and achieved much better results than a linear regression model and a support vector machine. We also demonstrate that using transfer learning techniques for the quantification of seagrass significantly improved the results as compared to directly applying the deep models to new locations.
Highlights
Seagrass constitutes a significantly important economic, ecological, and social well-being component of coastal ecosystems [1,2]
To address the first question, we develop two deep learning models for seagrass quantification: (1) a convolutional neural network (CNN) for regression of leaf area index (LAI), and a deep capsule network (DCN) that is optimized jointly for simultaneous classification and regression
Our results show that both DCN and CNN outperform linear regression and SVM, which demonstrates that information in the learned representations is more suitable than raw image patches for LAI quantification
Summary
Seagrass constitutes a significantly important economic, ecological, and social well-being component of coastal ecosystems [1,2]. Seagrass ecosystems are valued 33 and 23 times more than oceanic and terrestrial ecosystems, respectively. Seagrass provides numerous benefits such as organic fertilization, sediment trapping, or pollution filtering [2]. This paper analyzes different deep learning approaches for quantification of seagrass in satellite images and compares them against traditional machine learning methods. Our methods quantify the leaf area index (LAI) of each pixel based on multispectral satellite images. LAI is defined as leaf area per square area [3], and it is a critical biophysical component of seagrass [2]. The LAI index is denoted as a floating number ranging from 0 to 10, with ’0’ as no seagrass and ’10’ as the largest seagrass density per area
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