Optimization and Prediction Changes of Groundwater Quality Parameters Using ANN+PSO and ANN+P-PSO Models
(Case Study: Dezful Plain)
Subject Areas :
Water and Environment
Fahimeh Sayadi Shahraki
1
,
Abdolrahim hooshmand
2
,
Atefeh Sayadi Shahraki
3
1 - Faculty Member of Department of Electrical Engineering Faculty of Engineering, Islamic Azad University of Shahrekord. *(Corresponding author)
2 - Associated Professor, Irrigation and Drainage, Shahid Chamran University of Ahvaz.
3 - PhD, Irrigation and Drainage, Shahid Chamran University of Ahvaz
Received: 2016-08-29
Accepted : 2016-11-21
Published : 2021-06-22
Keywords:
Water quality,
Dezful,
predicted,
Particle Swarm Optimization Algorithm,
Abstract :
Background and Objective: One of the main aims of water resource planners and managers is the estimation and prediction of groundwater quality parameters to make managerial decisions. In this regard, many models have been developed which proposed better managements in order to maintain water quality. Most of these models require input parameters which are hardly available or their measurements are time consuming and expensive. Among them, Artificial Neural Network (ANN) models inspired by human's brain are a better choice.Method: The present study stimulated the groundwater quality parameters of Dezful plain including Sodium Adsorption Ratio (SAR), Electrical Conductivity (EC), Total Dissolved Solids (TDS), using ANN+PSO and ANN+P-PSO models and in the end is comparing their results with measured data. The input data for TDS quality parameter consist of EC, SAR, pH, SO4, Ca, Mg and Na, for SAR including the TDS, pH, Na, Hco3 and quality parameter of EC contains So4, Ca, Mg, SAR and pH, gathered from 2011 to 2015.Findings: The results indicated that the highest prediction accuracy of quality parameters of SAR, EC and TDS is related to the ANN+P-PSO model so that the MAE and RMSE statistics have the minimum and has the maximum value for the model. The results showed that RMSE for PSO in predicting SAR, EC and TDS were 0.09, 0.045 (µs/cm) and 0.053 (mg/l) in testing period, respectively. These statistical criteria were 0.039, 0.031 (µs/cm) and 0.045 (mg/l) for P-PSO in this period, respectively.Discussion and Conclusion: The results showed that P-PSO had more accuracy compared to PSO. In addition, there were no significant differences between ANN and collecting values. So, it is recommended that ANN were applied to determine nitrate concentration in groundwater.
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Eberhart, R. And Shi, Y. 2000. Comparing inertia weights and constriction factors in particle swarm, in: Proceedings of the Congress on Evolutionary Computation, 16-19 Jul 2000, La Jolla; pp. 84–88.
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Misaghi, F. and Mohammadi, K. 2004. Predicting changes in water quality of Zayandehrud river using artificial neural networks. The Second National Student Conference on Water and Soil Resources, Shiraz University. (In Persian)
Alizadeh, A., 2001. Principles of Applied Hydrology. 3thed. Mashhad: Astan Qods Razavi Publishing.
Kuo, Y-M, Liu, C-W. And Lin, K-H. 2004. Evaluation of the ability of an artificial neural network model to assess the variation of groundwater quality in an area of blackfoot disease in Taiwan. Water Research, Vol. 38(1), pp. 148-58.
Noorani, V. And Salehi, K. 2008. Modeling of rainfall – runoff using fuzzy neural network and adaptive neural networks and fuzzy inference methods compare. Pro ceedings of 4th National Congress on Civil Engineering; Tehran.
Asadollahfardi, A., Taklifi, Gh. and Ghanbari A. 2012. Application of artificial neural network to predict TDS in Talkheh Rud River. Journal of Irrigation and Drainage Engineering. Vol. 138, pp. 363–370.
Musavi-Jahromi, SH. And Golabi, M. 2008. Application of artificial neural networks in the river water quality modeling: Karoon river, Iran. Journal of Applied Sciences, Vol. 8, pp. 2324-28.
Najah, A., Elshafie. A., Karim, OA. And Jaffar, O. 2009. Prediction of Johor river water quality parameters using artificial neural networks. European Journal of Scientific Research, Vol. 28, pp. 422-35.
Banejad, H., Kamali, M., Amirmoradi, K. and Olyaie, F. 2013. Forecasting some of the Qualitative Parameters of Rivers Using Wavelet Artificial Neural Network Hybrid (W-ANN) Model (Case of study: Jajroud River of Tehran and Gharaso River of Kermanshah). Journal Health & Environ., Vol. 6, pp. 277-294. (In Persian)
Mirzavand, M., Sadati Nrjad, M. and Akbari, M. 2015. Simulation Changes in groundwater quality with artificial neural network model (Case study: Kashan aquifer). Iranian Journal of Natural Resources, Vol. 68, pp. 159-171. (In Persian)
Sayadi Shahraki, A. and Naseri, A. A. 2016. Simulation of Groundwater Nitrate Concentration Using Artificial Neural Network and Particle Accumulation Algorithms (PSO) and Genetics (GA) (Case Study: Behbahan Plain). Journal of Environmental Science and Technology, in turn. (In Persian)
Adib, A. and Zamani, R. 2015. Evaluation of the Spatial Variability of Groundwater Quality Factors in The Dezful Plain Using Geostatistics Methods. Journal of Water Resources Engineering, Vol. 8, pp. 1-12. (In Persian)
Eberhart, R. And Shi, Y. 2000. Comparing inertia weights and constriction factors in particle swarm, in: Proceedings of the Congress on Evolutionary Computation, 16-19 Jul 2000, La Jolla; pp. 84–88.
