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Your search keyword '"Sotiriadi, Nazar"' showing total 8 results
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8 results on '"Sotiriadi, Nazar"'

1. Climate Change Impact on Agricultural Land Suitability: An Interpretable Machine Learning-Based Eurasia Case Study

Author

Shevchenko, Valeriy, Taniushkina, Daria, Lukashevich, Aleksander, Bulkin, Aleksandr, Grinis, Roland, Kovalev, Kirill, Narozhnaia, Veronika, Sotiriadi, Nazar, Krenke, Alexander, and Maximov, Yury

Subjects
Computer Science - Machine Learning
Abstract

The United Nations has identified improving food security and reducing hunger as essential components of its sustainable development goals. As of 2021, approximately 828 million people worldwide are experiencing hunger and malnutrition, with numerous fatalities reported. Climate change significantly impacts agricultural land suitability, potentially leading to severe food shortages and subsequent social and political conflicts. To address this pressing issue, we have developed a machine learning-based approach to predict the risk of substantial land suitability degradation and changes in irrigation patterns. Our study focuses on Central Eurasia, a region burdened with economic and social challenges. This study represents a pioneering effort in utilizing machine learning methods to assess the impact of climate change on agricultural land suitability under various carbon emissions scenarios. Through comprehensive feature importance analysis, we unveil specific climate and terrain characteristics that exert influence on land suitability. Our approach achieves remarkable accuracy, offering policymakers invaluable insights to facilitate informed decisions aimed at averting a humanitarian crisis, including strategies such as the provision of additional water and fertilizers. This research underscores the tremendous potential of machine learning in addressing global challenges, with a particular emphasis on mitigating hunger and malnutrition.

Published
2023

2. Assessing the Risk of Permafrost Degradation with Physics-Informed Machine Learning

Author

Pilyugina, Polina, Chernikov, Timofey, Zaytsev, Alexey, Bulkin, Alexander, Burnaev, Evgeny, Belalov, Ilya, Sotiriadi, Nazar, Maximov, Yury, and Anisimov, Oleg

Subjects
Physics - Geophysics, Physics - Data Analysis, Statistics and Probability
Abstract

Global warming accelerates permafrost degradation, impacting the reliability of critical infrastructure used by more than five million people daily. Furthermore, permafrost thaw produces substantial methane emissions, further accelerating global warming and climate change and putting more than eight billion people at additional risk. To mitigate the upcoming risk, policymakers and stakeholders must be given an accurate prediction of the thaw development. Unfortunately, comprehensive physics-based permafrost models require location-specific fine-tuning that is challenging in practice. Models of intermediate complexity require few input parameters but have relatively low accuracy. The performance of pure data-driven models is low as well as the observational data is sparse and limited. In this work, we designed a physics-informed machine-learning approach for permafrost thaw prediction. The method uses a heat equation to regularize data-driven approach trained over permafrost monitoring data and climate projections. The latter leads to higher precision and better numerical stability allowing for reliable decision-making or construction and maintenance in the areas endangered by permafrost thaw with a time horizon of decades., Comment: 30 pages, 24 figures

Published
2023

3. Long-term drought prediction using deep neural networks based on geospatial weather data

Author

Marusov, Alexander, Grabar, Vsevolod, Maximov, Yury, Sotiriadi, Nazar, Bulkin, Alexander, and Zaytsev, Alexey

Subjects
Computer Science - Machine Learning
Abstract

The problem of high-quality drought forecasting up to a year in advance is critical for agriculture planning and insurance. Yet, it is still unsolved with reasonable accuracy due to data complexity and aridity stochasticity. We tackle drought data by introducing an end-to-end approach that adopts a spatio-temporal neural network model with accessible open monthly climate data as the input. Our systematic research employs diverse proposed models and five distinct environmental regions as a testbed to evaluate the efficacy of the Palmer Drought Severity Index (PDSI) prediction. Key aggregated findings are the exceptional performance of a Transformer model, EarthFormer, in making accurate short-term (up to six months) forecasts. At the same time, the Convolutional LSTM excels in longer-term forecasting.

Published
2023

7. Long-term drought prediction using deep neural networks based on geospatial weather data

Author

Grabar, Vsevolod, Marusov, Alexander, Maximov, Yury, Sotiriadi, Nazar, Bulkin, Alexander, Zaytsev, Alexey, Grabar, Vsevolod, Marusov, Alexander, Maximov, Yury, Sotiriadi, Nazar, Bulkin, Alexander, and Zaytsev, Alexey

Abstract

The problem of high-quality drought forecasting up to a year in advance is critical for agriculture planning and insurance. Yet, it is still unsolved with reasonable accuracy due to data complexity and aridity stochasticity. We tackle drought data by introducing an end-to-end approach that adopts a spatio-temporal neural network model with accessible open monthly climate data as the input. Our systematic research employs diverse proposed models and five distinct environmental regions as a testbed to evaluate the efficacy of the Palmer Drought Severity Index (PDSI) prediction. Key aggregated findings are the exceptional performance of a Transformer model, EarthFormer, in making accurate short-term (up to six months) forecasts. At the same time, the Convolutional LSTM excels in longer-term forecasting. Both models achieved high ROC AUC scores: 0.948 for one month ahead and 0.617 for twelve months ahead forecasts.

Published
2023

8. Flood Extent and Volume Estimation Using Remote Sensing Data.

Author

Popandopulo, Georgii, Illarionova, Svetlana, Shadrin, Dmitrii, Evteeva, Ksenia, Sotiriadi, Nazar, and Burnaev, Evgeny

Subjects
ARTIFICIAL neural networks, REMOTE sensing, FLOOD damage, FLOODS, INFRASTRUCTURE (Economics), WEATHER, PIPELINE inspection
Abstract

Floods are natural events that can have a significant impacts on the economy and society of affected regions. To mitigate their effects, it is crucial to conduct a rapid and accurate assessment of the damage and take measures to restore critical infrastructure as quickly as possible. Remote sensing monitoring using artificial intelligence is a promising tool for estimating the extent of flooded areas. However, monitoring flood events still presents some challenges due to varying weather conditions and cloud cover that can limit the use of visible satellite data. Additionally, satellite observations may not always correspond to the flood peak, and it is essential to estimate both the extent and volume of the flood. To address these challenges, we propose a methodology that combines multispectral and radar data and utilizes a deep neural network pipeline to analyze the available remote sensing observations for different dates. This approach allows us to estimate the depth of the flood and calculate its volume. Our study uses Sentinel-1, Sentinel-2 data, and Digital Elevation Model (DEM) measurements to provide accurate and reliable flood monitoring results. To validate the developed approach, we consider a flood event occurred in 2021 in Ushmun. As a result, we succeeded to evaluate the volume of that flood event at 0.0087 km3. Overall, our proposed methodology offers a simple yet effective approach to monitoring flood events using satellite data and deep neural networks. It has the potential to improve the accuracy and speed of flood damage assessments, which can aid in the timely response and recovery efforts in affected regions. [ABSTRACT FROM AUTHOR]

Published
2023
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