Abstract
Fast soil moisture content (SMC) mapping is necessary to support water resource management and to understand crop growth, quality, and yield. Therefore, earth observation (EO) plays a key role due to its ability of almost real-time monitoring of large areas at a low cost. This study aimed to explore the possibility of taking advantage of freely available Sentinel-1 (S1) and Sentinel-2 (S2) EO data for the simultaneous prediction of SMC with cycle-consistent adversarial network (CycleGAN) for time-series gap filling. The proposed methodology, first, learns latent low-dimensional representation of the satellite images, then learns a simple machine learning (ML) model on top of these representations. To evaluate the methodology, a series of vineyards, located in South Australia ’s Eden valley are chosen. Specifically, we presented an efficient framework for extracting latent features from S1 and S2 imagery. We showed how one could use S1 to S2 feature translation based on CycleGAN using S1 and S2 time series when there are missing images acquired over an area of interest. The resulting data in our study is then used to fill gaps in time-series data. We used the resulting latent representations to predict SMC with various ML tools. In the experiments, CycleGAN and the autoencoders were trained with data randomly chosen around the site of interest, so we could augment the existing dataset. The best performance was demonstrated with random forest (RF) algorithm, whereas linear regression model demonstrated significant overfitting. The experiments demonstrate that the proposed methodology outperforms the compared state-of-the-art methods if there are missing optical and synthetic-aperture radar (SAR) images.
Highlights
T ODAY, more than ever, new technologies are released to increase efficiency and productivity in agriculture due to increasing food demands and decreasing freshwater sources
With this low-dimensional representation data, soil moisture content (SMC) estimation is performed using various prediction models which are presented with their respective accuracy assessments
CycleGAN methodology is proposed for monitoring any biophysical parameters using S1 and S2 data
Summary
T ODAY, more than ever, new technologies are released to increase efficiency and productivity in agriculture due to increasing food demands and decreasing freshwater sources. One of the many industries embracing precision agriculture solutions using big data analytics is the viticulture industry, which is growing rapidly and steadily. For this branch of horticulture, improving water efficiency is one of the most profound problems. Corresponding author: Esra Erten in viticulture, seek cost-effective ways to monitor soil moisture (SM) content. During the last decades, a lot of work has documented the potential of Earth Observation (EO) data for soil moisture monitoring in agriculture due to their potential to supply spatio-temporal information over large areas and being complementary to in-situ data [1]
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