Abstract
Remote-sensing-driven urban change detection has been studied in many ways for decades for a wide field of applications, such as understanding socio-economic impacts, identifying new settlements, or analyzing trends of urban sprawl. Such kinds of analyses are usually carried out manually by selecting high-quality samples that binds them to small-scale scenarios, either temporarily limited or with low spatial or temporal resolution. We propose a fully automated method that uses a large amount of available remote sensing observations for a selected period without the need to manually select samples. This enables continuous urban monitoring in a fully automated process. Furthermore, we combine multispectral optical and synthetic aperture radar (SAR) data from two eras as two mission pairs with synthetic labeling to train a neural network for detecting urban changes and activities. As pairs, we consider European Remote Sensing (ERS-1/2) and Landsat 5 Thematic Mapper (TM) for 1991–2011 and Sentinel 1 and 2 for 2017–2021. For every era, we use three different urban sites—Limassol, Rotterdam, and Liège—with at least 500km2 each, and deep observation time series with hundreds and up to over a thousand of samples. These sites were selected to represent different challenges in training a common neural network due to atmospheric effects, different geographies, and observation coverage. We train one model for each of the two eras using synthetic but noisy labels, which are created automatically by combining state-of-the-art methods, without the availability of existing ground truth data. To combine the benefit of both remote sensing types, the network models are ensembles of optical- and SAR-specialized sub-networks. We study the sensitivity of urban and impervious changes and the contribution of optical and SAR data to the overall solution. Our implementation and trained models are available publicly to enable others to utilize fully automated continuous urban monitoring.
Highlights
Remote-sensing-driven urban change detection has been studied in many ways for decades for a wide field of applications, such as understanding socio-economic impacts, identifying new settlements, or analyzing trends of urban sprawl
We propose an ensemble neural network architecture called the Ensemble of Recurrent Convolutional Neural Networks for Deep Remote Sensing (ERCNN-DRS)
Our goal is to offer a trained network that can be applied with minimal effort to an Areas of Interest (AoI) for a short period of 1y for ERS-1/2 and Landsat 5 Thematic Mapper (TM), or 6m for Sentinel 1 and 2 mission pairs
Summary
Remote-sensing-driven urban change detection has been studied in many ways for decades for a wide field of applications, such as understanding socio-economic impacts, identifying new settlements, or analyzing trends of urban sprawl. Due to the reliance of repeat cycles and sensor technologies of satellite-based remote sensing, it is sought after by urban change detection to understand socio-economic impacts and effects, identifying new settlements, monitoring urban growth, or analyzing trends of urban sprawl, just to name a few. For these fields, knowledge of how urban and human-made structures change over time is crucial and, depending on the exact application, can require high spatio-temporal resolution. We propose an ensemble neural network architecture called the Ensemble of Recurrent Convolutional Neural Networks for Deep Remote Sensing (ERCNN-DRS)
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