Semi-Supervised Adversarial Domain Adaptation for Seagrass Detection in Multispectral Images

Seagrass form the basis for critically important marine ecosystems. Previously, we implemented a deep convolutional neural network (CNN) model to detect seagrass in multispectral satellite images of three coastal habitats in northern Florida. However, a deep CNN model trained at one location usually does not generalize to other locations due to data distribution shifts. In this paper, we developed a semi-supervised domain adaptation method to generalize a trained deep CNN model to other locations for seagrass detection. First, we utilized a generative adversarial network (GAN) loss to align marginal data distribution between source domain and target domain using unlabeled data from both data domains. Second, we used a few labelled samples from the target domain to align class specific data distributions between the two domains, based on the contrastive semantic alignment loss. We achieved the best results in 28 out of 36 scenarios as compared to other state-of-the-art domain adaptation methods.

[1]  Benlin Xiao,et al.  Aquatic vegetation mapping based on remote sensing imagery: An application to Honghu Lake , 2011, 2011 International Conference on Remote Sensing, Environment and Transportation Engineering.

[2]  Peter Reinartz,et al.  CUBESAT-DERIVED DETECTION OF SEAGRASSES USING PLANET IMAGERY FOLLOWING UNMIXING-BASED DENOISING: IS SMALL THE NEXT BIG? , 2017 .

[3]  Stuart R. Phinn,et al.  Integrating Quickbird Multi-Spectral Satellite and Field Data: Mapping Bathymetry, Seagrass Cover, Seagrass Species and Change in Moreton Bay, Australia in 2004 and 2007 , 2011, Remote. Sens..

[4]  Dingtian Yang,et al.  Detection of seagrass in optical shallow water with Quickbird in Xincun Bay of Hainan province, China , 2009, 2009 IEEE International Workshop on Imaging Systems and Techniques.

[5]  Donald A. Adjeroh,et al.  Unified Deep Supervised Domain Adaptation and Generalization , 2017, 2017 IEEE International Conference on Computer Vision (ICCV).

[6]  L. Su,et al.  Seagrass Resource Assessment Using WorldView-2 Imagery in the Redfish Bay, Texas , 2019, Journal of Marine Science and Engineering.

[7]  Heidi M. Dierssen,et al.  Evaluating Light Availability, Seagrass Biomass, and Productivity Using Hyperspectral Airborne Remote Sensing in Saint Joseph’s Bay, Florida , 2014, Estuaries and Coasts.

[8]  Jiang Li,et al.  Seagrass Detection in Coastal Water Through Deep Capsule Networks , 2018, PRCV.

[9]  Jiang Li,et al.  DeepCoast: Quantifying Seagrass Distribution in Coastal Water Through Deep Capsule Networks , 2018, PRCV.

[10]  Md. Moniruzzaman,et al.  Imaging and Classification Techniques for Seagrass Mapping and Monitoring: A Comprehensive Survey , 2019, ArXiv.

[11]  Trevor Darrell,et al.  Adversarial Discriminative Domain Adaptation , 2017, 2017 IEEE Conference on Computer Vision and Pattern Recognition (CVPR).

[12]  Serge Andréfouët,et al.  Sea surface correction of high spatial resolution Ikonos images to improve bottom mapping in near-shore environments , 2003, IEEE Trans. Geosci. Remote. Sens..

[13]  Peter Reinartz,et al.  Mapping Mediterranean seagrasses with Sentinel-2 imagery. , 2017, Marine pollution bulletin.

[14]  Leanne Claire Cullen-Unsworth,et al.  Secret Gardens Under the Sea: What are Seagrass Meadows and Why are They Important? , 2018, Front. Young Minds..

[15]  Thomas Heege,et al.  Benthic habitat and bathymetry mapping of shallow waters in Puerto morelos reefs using remote sensing with a physics based data processing , 2012, 2012 IEEE International Geoscience and Remote Sensing Symposium.