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Earth Science Informatics
Erschienen in: Earth Science Informatics 4/2023

31.08.2023 | Research

Prediction of groundwater level variations using deep learning methods and GMS numerical model

verfasst von: Siamak Amiri, Ahmad Rajabi, Saeid Shabanlou, Fariborz Yosefvand, Mohammad Ali Izadbakhsh

Erschienen in: Earth Science Informatics | Ausgabe 4/2023

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Abstract

One of the key elements of the hydrogeological cycle and a variable used by many water resource operating models is the variation in groundwater level (GWL). One of the biggest obstacles to the drawdown analysis and GWL forecasts is the absence of accurate and complete data. The application of diverse numerical models has been regarded as a reliable approach in recent years. Such models are able to determine the GWL for any given region by utilising a wide variety of statistics, data, and field measurements such as pumping experiments, geophysics, soil and land use maps, topography and slope data, a plethora of boundary conditions, and the application of complex equations. Artificial intelligence-based models need significantly less information. The purpose of this research is to predict the changes of GWL of Shazand plain by using the PSO-ANN, ACA-ANN hybrid methods and deep learning methods LSTM, LS-SVM, and ORELM and comparing with GMS numerical model. The model’s accuracy is evaluated using a two-stage validation and verification process. Then Taylor’s diagram was used to select the best model. Results show that ORELM with R, Nash, RMSE and NRMSE values equal to 0.977, 0.955, 0.512 and 0.058 respectively was the best performance in the test stage. After that is the PSO-ANN model. Using the Taylor diagram is another certain way to guarantee that you’ve picked the best possible model. The research results show that there is a link between the ORELM and the place that is most central to the reference point. Since the GMS model is complex and requires a large amount of data and a time-consuming calibration and validation process, the ORELM model can be utilised with certainty to predict the GWL across the entire plain. This research suggests that instead of using numerical models with a complex and time-consuming structure, deep learning methods with the least required data and with high accuracy should be used to forecast the groundwater level.
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Literatur
Azari A, Zeynoddin M, Ebtehaj I, Sattar AMA, Gharabaghi B, Bonakdari H (2021) Integrated preprocessing techniques with linear stochastic approaches in GWL forecasting. Acta Geophysica 69:1395–1411
Azizpour A, Izadbakhsh MA, Shabanlou S, Yosefvand F, Rajabi A (2021) Estimation of water level fluctuations in groundwater through a hybrid learning machine. Groundw Sustain Dev 15:100687
Azizpour A, Izadbakhsh MA, Shabanlou SY, Rajabi F (2022) A simulation of time-series groundwater parameters using a hybrid metaheuristic neuro-fuzzy model. Environ Sci Pollut Res 29:28414–28430
Bayesteh M, Azari A (2021) Stochastic optimization of reservoir operation by applying hedging rules. J Water Resour Plan Manag 147(2):04020099
Bilali AE, Lamane H, Taleb A, Nafii A (2022) A framework based on multivariate distribution-based virtual sample generation and DNN for predicting water quality with small data. J Clean Prod 368:133227
Bilali AE, Taleb A, Brouziyne B (2021) Comparing four machine learning model performances in forecasting the alluvial aquifer level in a semi-arid region. J Afr Earth Sci 181:104244
Erturk A, Ekdal A, Gurel M, Karakaya N, Guzel C, Gonenc E (2014) Evaluating the impact of climate change on groundwater resources in a small Mediterranean watershed. Sci Total Environ 499:437–447
Fleckenstein JH, Krause S, Hannah DM, Boano F (2010) Groundwater-surface water interactions-new methods and models to improunderstanding of processes and dynamics. J Adv Water Resource 33:1291–1295
Goorani Z, Shabanlou S (2021) Multi-objective optimization of quantitative-qualitative operation of water resources systems with approach of supplying environmental demands of Shadegan Wetland. J Environ Manag 292:112769
Graham PW, Andersen MS, McCabe MF, Ajami H, Baker A, Acworth I (2015) To what xtent do long-duration high-volume dam releases influence river–aquifer interactions? A case study in New South Wales, Australia. Hydrogeol J 23:319–334
Guzman SM, Paz JO, Tagert MLM, Mercer AE (2019) Evaluation of seasonally classified inputs for the prediction of daily GWLs: NARX networks vs support vector machines. Environ Model Assess 24(2):223–234
Hu L, Xu Z, Huang W (2016) Development of a river-groundwater interaction model and its application to a catchment in northwestern China. J Hydrol 543:483–500
Huang GB, Zhu QY, Siew CK (2006) Extreme learning machine: theory and applications. Neurocomputing 70(1–3):489–501
Irawan D, Puradimaja D, Silaen H (2011) Hydrodynamic Relationshipbetween ManMade Lake and Surrounding Aquifer, Cimahi, Banduge,Indonesia. J World Acad Sci Eng Technol 58:100–103
Ivkovic KM (2009) A top–down approach to characterise aquifer–river interaction processes. J Hydrol 365:145–155
Klove B, Ala-Aho P, Bertrand G, Gurdak JJ, Kupfersberger H, Kværner J, PulidoVelazquez M (2014) Climate change impacts on groundwater and dependent ecosystems. J Hydrol 518:250–266
Lachaal F, Mlayah A, Bedir M, Tarhouni J, Leduc C (2012) Implementation of a 3-D and GIS tools: the Zeramdine-Beni Hassen Mioceneaquifer system (east-central Tunisisa). J Comput Geosci 48:187–198
Lemieux J, Hassaoui J, Molson J, Therrien R, Therrien P, Chouteau M, Ouellet M (2015) Simulating the impact of climate change onthe groundwater resources of the Magdalen Islands. J Hydrol 3:400–423
Malekzadeh M, Kardar S, Shabanlou S (2019b) Simulation of groundwater level using MODFLOW, extreme learning machine and wavelet-extreme learning machine models. Groundwater for sustainable development. Groundwater for. Sustain Dev 9:100279
Mohammed KS, Shabanlou S, Rajabi A, Yosefvand F, Izadbakhsh MA (2023) Prediction of groundwater level fluctuations using artificial intelligence-based models and GMS. Appl Water Sci 13(2):54
Moradi A, Akhtari A, Azari A (2023) Prediction of groundwater level fluctuation using methods based on machine learning and numerical model. J Appl Res Water Wastewater 10(1):20–28
Nadiri AA, Naderi K, Khatibi R, Gharekhani M (2019) Modelling GWL variations by learning from multiple models using fuzzy logic. Hydrol Sci J 64(2):210–226
Pahar G, Dhar A (2014) A dry zone-wet zone based modeling of surface water and groundwater interaction for generalized ground profile. J Hydrol 519(27):2215–2223
Panda DK, Mishra A, Kumar A (2012) Quantification of trends in GWLs of Gujarat in western India. Hydrol Sci J 57(7):1325–1336
Paul A, Afroosa M, Baduru B, Paul B (2023) Showcasing model performance across space and time using single diagrams. Ocean Model 181:102150
Poursaeid M, Mastouri R, Shabanlou S, Najarchi M (2021) Modelling qualitative and quantitative parameters of groundwater using a new wavelet conjunction heuristic method: wavelet extreme learning machine versus wavelet neural networks. Water Environ J 35:67–83
Poursaeid M, Mastouri R, Shabanlou S et al (2020) Estimation of total dissolved solids, electrical conductivity, salinity and groundwater levels using novel learning machines. Environ Earth Sci 79:453
Poursaeid M, Poursaeid AH, Shabanlou S (2022) A comparative study of artificial intelligence models and A statistical method for groundwater level prediction. Water Resour Manag 36:1499–1519
Ramírez-Hernández J, Hinojosa-Huerta Q, Peregrina-Llanes M, Calvo-Fonseca A, Carrera-Villa E (2013) Groundwater responses to controlled water releases in the limitrophe region of the Colorado River: Implications for management and restoration. J Ecol Eng 59:93–103
Samani S, Vadiati M, Delkash M, Bonakdari H (2022) A hybrid wavelet–machine learning model for qanat water flow prediction. Acta Geophysica:1–19
Samani S, Ye M, Zhang F, Pei YZ, Tang GP, Elshall A, Moghaddam AA (2018) Impacts of prior parameter distributions on Bayesian evaluation of groundwater model complexity. Water Sci Eng 11(2):89–100
Shrestha S, Bach TV, Pandey VP (2016) Climate change impacts on groundwater resources in Mekong Delta under representative concentration pathways (RCPs) scenarios. Environ Sci Pol 61:1–13
Soltani K, Azari A (2022) Forecasting groundwater anomaly in the future using satellite information and machine learning. J Hydrol 612(2):128052
Todd WR, Kenneth RB (2001) “Report: delineation of capture zones for municipal wells in fractured dolomite”. Sturgeon Bay, Wisconsin, USA. Hydrogeol J 9:432–450
Xie YC, Shanafield PG, Simmons M, Zheng CT, C. (2016) Uncertainty of natural tracer methods for quantifying river–aquifer interaction in a large river. J Hydrol 535:135–147
Yanxun S, Yuan F, Hui Q, Xuedi Z (2011) Research and Application ofGroundwater Numerical Simulation-A Case Study in Balasu Water Source. Proced Environ Sci 8:146–152
Yosefvand F, Shabanlou S (2020) Forecasting of groundwater level using ensemble hybrid wavelet–self-adaptive extreme learning machine-based models. Nat Resour Res 29:3215–3232
Zampieri M, Serpetzoglou E, Anagnostou EN, Nikolopoulos EI, Papadopoulos A (2012) Improving the representation of river–groundwater interactions in land surface modeling at the regional scale: observational evidence and parameterization applied in the community land model. J Hydrol 420(421):72–86
Zeinali M, Azari A, Heidari M (2020a) Simulating unsaturated zone of soil for estimating the recharge rate and flow exchange between a river and an aquifer. Water Resour Manag 34:425–443
Zeinali M, Azari A, Heidari M (2020b) Multiobjective Optimization for Water Resource Management in Low-Flow Areas Based on a Coupled Surface Water–Groundwater Model. J Water Resource Plann Manag (ASCE) 146(5):04020020
Zeynoddin M, Bonakdari H, Azari A, Ebtehaj I, Gharabaghi B, Madavar HR (2018) Novel hybrid linear stochastic with non-linear extreme learning machine methods for forecasting monthly rainfall a tropical climate. J Environ Manag 222:190–206
Zeynoddin M, Bonakdari H, Ebtehaj I, Azari A, Gharabaghi B (2020) A generalized linear stochastic model for lake level prediction. Sci Total Environ 723:138015
Zhang K, Luo M (2015) Outlier-robust extreme learning machine for regression problems. Neurocomputing 151:1519–1527
Metadaten
Titel
Prediction of groundwater level variations using deep learning methods and GMS numerical model
verfasst von
Siamak Amiri
Ahmad Rajabi
Saeid Shabanlou
Fariborz Yosefvand
Mohammad Ali Izadbakhsh
Publikationsdatum
31.08.2023
Verlag
Springer Berlin Heidelberg
Erschienen in
Earth Science Informatics / Ausgabe 4/2023
Print ISSN: 1865-0473
Elektronische ISSN: 1865-0481
DOI
https://doi.org/10.1007/s12145-023-01052-1

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