Abstract
Biological data sets are increasingly becoming information-dense, making it effective to use a computer science-based analysis. We used convolution neural networks (CNN) and the specific CNN architecture Unet to study sponge behavior over time. We analyzed a large time series of hourly high-resolution still images of a marine sponge, Suberites concinnus (Demospongiae, Suberitidae) captured between 2012 and 2015 using the NEPTUNE seafloor cabled observatory, off the west coast of Vancouver Island, Canada. We applied semantic segmentation with the Unet architecture with some modifications, including adapting parts of the architecture to be more applicable to three-channel images (RGB). Some alterations that made this model successful were the use of a dice-loss coefficient, Adam optimizer and a dropout function after each convolutional layer which provided losses, accuracies and dice scores of up to 0.03, 0.98 and 0.97, respectively. The model was tested with five-fold cross-validation. This study is a first step towards analyzing trends in the behavior of a demosponge in an environment that experiences severe seasonal and inter-annual changes in climate. The end objective is to correlate changes in sponge size (activity) over seasons and years with environmental variables collected from the same observatory platform. Our work provides a roadmap for others who seek to cross the interdisciplinary boundaries between biology and computer science.
Highlights
How animals react to their surroundings is a complicated function of physiology, anatomy, and life history traits [1,2,3,4]
The architecture of the model had a total of 1,941,105 trainable parameters and zero non-trainable parameters
In this work we used a modified Unet architecture under the umbrella of a convolution neural networks (CNN) deep learning model to extract the image of a demosponge from a complex, colored background for a study of sponge behaviour
Summary
How animals react to their surroundings is a complicated function of physiology, anatomy, and life history traits [1,2,3,4]. Extremes of the temporal scale of behaviors in marine invertebrates range from the snapping punch of the mantis shrimp that boils the water in front of it in milliseconds [17], to the slow stroll of a sea urchin on its tube feet along the ocean floor, for hours or days [18]. To understand these activities in the context of the animal’s ecology, heterogeneous data, including physical, chemical and biological variables need to be acquired over the same time period. The relevant information in these data can only be fully accessed using the appropriate artificial intelligence methodologies, which are capable of discovering underlying trends and unexpected relationships among the range of environmental and biological variables
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