Abstract
In this paper, we propose a series of procedures for coastal wave-tracking using coastal video imagery with deep neural networks. It consists of three stages: video enhancement, hydrodynamic scene separation and wave-tracking. First, a generative adversarial network, trained using paired raindrop and clean videos, is applied to remove image distortions by raindrops and to restore background information of coastal waves. Next, a hydrodynamic scene of propagated wave information is separated from surrounding environmental information in the enhanced coastal video imagery using a deep autoencoder network. Finally, propagating waves are tracked by registering consecutive images in the quality-enhanced and scene-separated coastal video imagery using a spatial transformer network. The instantaneous wave speed of each individual wave crest and breaker in the video domain is successfully estimated through learning the behavior of transformed and propagated waves in the surf zone using deep neural networks. Since it enables the acquisition of spatio-temporal information of the surf zone though the characterization of wave breakers inclusively wave run-up, we expect that the proposed framework with the deep neural networks leads to improve understanding of nearshore wave dynamics.
Highlights
The understanding of wave dynamics in the nearshore is still challenging because of the high variability of the nearshore wave process in both the surf and swash zones
We introduced deep neural network approach to tracking waves using coastal video imagery in the surf and swash zones
It contains wave-tracking and video enhancement to improve the quality of images contaminated by raindrops and hydrodynamic scene separation to extract only the movement of waves excluding the effects of ambient light
Summary
The understanding of wave dynamics in the nearshore is still challenging because of the high variability of the nearshore wave process in both the surf and swash zones. A few studies have been published on tracking individual waves across a cross-shore transect of interest in coastal video imagery on the surf and swash zone of natural beaches. Yoo et al [2] used filter-based image processing methods, in particular Radon transformation [3], to track individual waves on time-space images, the called timestacks images, which do not contain the full variability of wave parameters in the surf zone. Vousdoukas et al [4] introduced wave run-up measurements based on timestack images generated from coastal video imagery by extracting and processing time series of the cross-shore position of the swash extrema. The estimated wave run-up height was more accurate than those from available
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