Flood Stage Forecasting Using Machine-Learning Methods: A Case Study on the Parma River (Italy)

Dazzi, Susanna; Vacondio, Renato; Mignosa, Paolo

doi:10.3390/w13121612

Cited by 46 publications

(32 citation statements)

References 46 publications

(73 reference statements)

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“…Overall, the 16 models were consistent in predicting 53.79% and 0.11% of the watershed as belonging to the very low and very high flood risk classes, respectively, while inconsistencies were observed for the remaining 46.10%. A total of 11 flood-conditioning factors, including curvature, elevation, distance to river, drainage density, slope, flow accumulation, precipitation, TWI, NDVI, SPI and WI, were selected as numerical variables, while five factors, including aspect, flow direction, geology, substrate resistance to erosion, and land use, were identified as categorical variables in mapping flood susceptibility based on the literature [30,[36][37][38][39][40][41][42][43][44][45].…”

Section: Models Results Comparisonmentioning

confidence: 99%

“…These include artificial neural network (ANN), which is one of the most widely used ML algorithms for flood risk prediction [21][22][23][24][25][26][27]. Other ML algorithms have been used to predict flood risk such as support vector machine [28][29][30], random forest (RF) [17,31,32], logistic regression [7], adaptive neuro-fuzzy inference system [33] and Long Short-term Memory [34,35].…”

Section: Introductionmentioning

confidence: 99%

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Spatial prediction of flood-susceptible zones in the Ourika watershed of Morocco using machine learning algorithms

Meliho

Khattabi

Zejli

et al. 2022

ACI

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PurposeThe purpose of the paper is to predict mapping of areas vulnerable to flooding in the Ourika watershed in the High Atlas of Morocco with the aim of providing a useful tool capable of helping in the mitigation and management of floods in the associated region, as well as Morocco as a whole.Design/methodology/approachFour machine learning (ML) algorithms including k-nearest neighbors (KNN), artificial neural network, random forest (RF) and x-gradient boost (XGB) are adopted for modeling. Additionally, 16 predictors divided into categorical and numerical variables are used as inputs for modeling.FindingsThe results showed that RF and XGB were the best performing algorithms, with AUC scores of 99.1 and 99.2%, respectively. Conversely, KNN had the lowest predictive power, scoring 94.4%. Overall, the algorithms predicted that over 60% of the watershed was in the very low flood risk class, while the high flood risk class accounted for less than 15% of the area.Originality/valueThere are limited, if not non-existent studies on modeling using AI tools including ML in the region in predictive modeling of flooding, making this study intriguing.

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Section: Models Results Comparisonmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Spatial prediction of flood-susceptible zones in the Ourika watershed of Morocco using machine learning algorithms

Meliho

Khattabi

Zejli

et al. 2022

ACI

View full text Add to dashboard Cite

show abstract

“…The weights are calculated by minimizing the mean square error between the output and the actual values. ASCE Task Committee on Application of Artificial Neural Networks in Hydrology (2000) provides a detailed survey of the numerous effective applications of ANNs to hydrological problems, e.g., estimating temperature (Cifuentes et al 2020), and precipitation (Lee et al 2018), modeling stream flows (Uysal et al 2016), forecasting river stages (Dazzi et al 2021), rainfall-runoff modeling (Riad et al 2004), water quality modeling (Rehana & Dhanya 2018;Zhu et al 2018), groundwater modeling (Ebrahimi & Rajaee 2017), and many other applications. More details of the ANN model and the training algorithms can be found in El- Baroudy et al (2010).…”

Section: Artificial Neural Network (Ann)mentioning

confidence: 99%

Prediction of land surface temperature of major coastal cities of India using bidirectional LSTM neural networks

Maddu

Vanga

Sajja

et al. 2021

Journal of Water and Climate Change

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Surface Temperature (ST) is important in terms of surface energy and terrestrial water balances affecting urban ecosystems. In this study, to process the nonlinear changes of climatological variables by leveraging the distinct advantages of Long Short-Term Memory (LSTM) and Bidirectional Long Short-Term Memory (BiLSTM), we propose an LSTM-BiLSTM hybrid deep learning model which extracts multi-dimension features of inputs, i.e., backward (future to past) or forward (past to future) to predict ST. This study assessed the climatological variables, i.e., wind speed, wind direction, relative humidity, dew point temperature, and atmospheric pressure impact on ST using five major coastal cities of India: Chennai, Mangalore, Visakhapatnam, Cuddalore, and Cochin. The Recurrent Neural Networks (RNN) and hybrid LSTM-BiLSTM models have effectively predicted ST and outperformed the standalone Artificial Neural Networks (ANN), LSTM, and BiLSTM models. The RNN and LSTM-BiLSTM models have performed better in predicting ST for Mangalore (Nash-Sutcliffe efficiency (NSE)=0.91), followed by Cochin (NSE=0.89), Chennai (NSE=0.88), Cuddalore (NSE=0.88), and Vishakhapatnam (NSE=0.81). The hybrid data-driven modeling framework indicated that coupling the LSTM and BiLSTM models were proven effective in predicting the ST of coastal cities.

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“…The application of AI to hydrology has largely focused on atmospheric modeling and image segmentation (Ball, Anderson, & Chan, 2017). However, there is a growing body of research using AI for modeling hydrologic variables (Nourani, Baghanam, Adamowski, & Kisi, 2014) such as flow (Alquraish, Abuhasel, Alqahtani, & Khadr, 2021), runoff (Han, Choi, Jung, & Kim, 2021;Kratzert et al, 2019), sediment, and flooding (Dazzi, Vacondio, & Mignosa, 2021;Han et al, 2021;Jiang, Xie, & Sainju, 2019;Schmidt, Heße, Attinger, & Kumar, 2020). Surface water modeling is informed by atmospheric modeling, yet hydrologic feature extraction often employs traditional image segmentation methods using reflectance and elevation data.…”

Section: Hydrographic Feature Extraction and Modelingmentioning

confidence: 99%

GeoAI in the US Geological Survey for topographic mapping

Usery

Arundel

Shavers

et al. 2021

Transactions in GIS

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The acquisition of nationwide data sets of high-resolution elevation, hydrography and associated data including transportation, trails, geographic names, structures, boundaries, land cover, and orthographic images is a current effort of the National Geospatial Program (NGP) of the USGS. The goal of this acquisition is to better record the USA's natural and built structures in support of science and decision applications for the US Geological Survey (USGS) and Department of Interior, as well as other federal and state agencies and the public. The frameworks and structure of these data sets, which are all core parts of the National Map, are provided in the 3D Elevation Program (3DEP) and National Hydrography Dataset (NHD) websites. Ongoing research in the field of spatial artificial intelligence applications known as geospatial artificial intelligence (GeoAI) aims to supplement the acquisition, processing, and use of these national data sets for mapping, modeling, and decision-making applications. This article will present current (2021) USGS work in feature extraction, multiscale processing, hydrography,

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Flood Stage Forecasting Using Machine-Learning Methods: A Case Study on the Parma River (Italy)

Cited by 46 publications

References 46 publications

Spatial prediction of flood-susceptible zones in the Ourika watershed of Morocco using machine learning algorithms

Spatial prediction of flood-susceptible zones in the Ourika watershed of Morocco using machine learning algorithms

Prediction of land surface temperature of major coastal cities of India using bidirectional LSTM neural networks

GeoAI in the US Geological Survey for topographic mapping

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