Abstract
In this research, a simulation–optimization (S/O) model is used in order to estimate aquifer parameters on two aquifers. In this model, meshless local Petrov–Galerkin (MLPG) is used for simulation purpose and modified teaching–learning-based optimization (MTLBO) algorithm is engaged as optimization model. Linking these two powerful models generates a S/O model named MLPG-MTLBO. The proposed model is applied on two aquifers: a standard and a real field aquifer. In standard aquifer, parameters are only transmissivity coefficients in x and y direction for three zones. The acquired results by MLPG-MTLBO are really close to true values. This fact presents the power of MLPG-MTLBO inverse model. Therefore, it is applied on field aquifer. Unconfined aquifer of Birjand recognized as real case study. Parameters which are needed to be estimated are specific yields and hydraulic conductivity coefficients. These parameters are computed by MLPG-MTLBO and entered to the groundwater flow model. The achieved groundwater table compared with observation data and RMSE is calculated. RMSE value is 0.356 m; however, this error criterion for MLPG and FDM is 0.757 m and 1.197 m, respectively. This means that estimation is precise and makes the RMSE to reduce from 0.757 to 0.356 m, and also, MLPG-MTLBO is an accurate model for this aim.
Similar content being viewed by others
Explore related subjects
Discover the latest articles, news and stories from top researchers in related subjects.Avoid common mistakes on your manuscript.
Introduction
Groundwater is one the most crucial resources that supply the water needs of human beings in different parts and zones (Das and Eldho 2022). As groundwater resources are laboriously renewable in nature and the renewing process takes a lot of time and money, a comprehensive plan must be sketched in a way that exploitation carry out in a proper and efficient manner.
Since groundwater resources are the only available sources of freshwater especially in arid zones, their behavior must be investigated and predicted accurately. For this purpose, simulation of groundwater flows in aquifers is a key work that must be considered for all the aquifers. In order to have a pervasive-accurate model, parameters of aquifers have a considerable role (Swathi and Eldho 2014). Therefore, there is a big need to have the parameters of aquifers in precise state.
It is extremely vital to analytically examine the aquifer parameters including transmissivity, hydraulic conductivity, and specific yield (Thomas et al. 2018). As there is no analytical model for groundwater flow just for some simple cases (Mategaonkar and Eldiho 2011), usage of numerical methods is recommended. These methods with linking to some other methods comprise an inverse modeling for aquifer parameter estimation.
The complicated groundwater flow can be analyzed by solving the governing equations with using numerical methods including analytical element method (AEM), finite element method (FEM), finite difference method (FDM), or boundary element method (BEM) (Mategaonkar and Eldho 2011).
As we mentioned before, there is no analytical solution for groundwater flow, using analytical element method (AEM) for estimating transient flow conditions is not satisfying and recommending. The aquifer system is mostly illustrated by a PDE which usually is studied using numerical methods such as FDM and FEM (Pinder and William 2013). Nevertheless, these methods have intrinsic drawbacks based on grids connected by mesh in a predetermined manner like significant expenses in creating grid, less-accurate estimations, and difficulty in adaptive analysis (Swathi and Eldho 2013). By using FDM and FEM solutions, a grid shapes over the domains and a tiresome preprocessing must be performed (Thomas et al. 2012). Numerical solutions, like FDM and FEM, have been applied to the majority of field problems (Wang and Anderson 1995).
There are many researches which used FDM and FEM for simulation of groundwaters. Panahi et al. (2016) used MODFLOW in order to investigate groundwater fluctuations in Zanjan aquifer. They estimated volume of aquifer and found it around 357 MCM. They have also used PEST for calibration of aquifer parameters. Abdelhalim et al. (2019) investigated the more extraction of groundwater from Egypt country on aquifer with MODFLOW. They considered some scenarios. They noted that if the extraction would increase about 25–50 percent, 38 thousand cubic meters would reduce from stored water daily.
Ansarifar et al. (2019) carried out a modeling for groundwater in a coastal aquifer named Bandar-Gaz with MODFLOW. The simulation was carried out on two steady and unsteady states. Their research showed the effect of sea level on hydraulic behavior of coastal aquifer (Ansarifar et al. 2019).
Recently, meshless numerical methods are used as alternatives numerical methods like FDM and FEM for solving more complicated problems easily and precisely (Liu and Gu 2005). The meshless techniques are defined as numerical solutions accustomed to set up a system of algebraical equations for the entire domain while not employing a predetermined grid for the model discretization (Liu 2002). Meshfree technique gets rid of the disadvantage of meshing that exists in FDM and FEM (Mohtashami et al. 2017). Using the nodes in meshless solutions for approximation of the governing equations declines the enormous work needed to predetermine for groundwater modeling such as in mesh-based methods (Mohtashami et al. 2022a). Myriad meshless-based strategies found their place in various applications and presented great potential as a remarkable and effective numerical solution tool.
Some of the usage of this methods in groundwater studies are explained.
Li et al. (2003) applied a MFree strategy based on collocation method with radial basis function to model contaminant transport of aquifer . They conducted that the method performed precisely and appropriately. Liu (2006) used radial point collocation method (RPCM) for solving convection–diffusion burger equation in 2D manner based on interpolation scheme. He illustrated that the model performed interestingly for solving fluid-based problems. Mategaonkar and Eldho (2011) applied a MFree model (polynomial point collocation method) to groundwater flow problems in porous media in both 1- and 2-dimensional manner. They illustrated that compared to analytical methods and FEM model, the meshless-based model was more satisfying. Mohtashami et al. (2021) used a meshless method for simulation of groundwater and linked it to particle filter in order to have more precise results.
Although the strategies and methods used to model groundwater systems are very important and each one provides different results, the input data to the models are also of particular importance as the main and initial tools to start the modeling process. As the input data to the model are natural in nature, they may not be uniformly and proportionally distributed in the groundwater system and may be associated with errors. Therefore, the validation and verification of input data to the model significantly influence the accuracy of the model results. Few works have been done to evaluate and validate data using an optimization algorithm. Simulation–optimization models are widely applied for predicting parameters of aquifer based on inverse modeling approach (Swathi and Eldho 2018).
Swathi et al. (2014) applied a MLPG model coupled with partial swarm optimization (PSO) to predict the behavior of groundwater system and optimize the input data simultaneously. Comparing to genetic algorithm (GA) and Levenberg–Marquardt algorithm (LMA), the coupled model represented better results. Thomas et al. (2018) used a simulation–optimization model based on radial point collocation meshfree method (RPCM) coupling with cat swarm optimization (CSO). The results of RPCM-CSO were more satisfying comparing to RPCM-PSO and RPCM-EMPSO (radial point collocation method coupling with elitist mutated partial swarm optimization.
In this study, with aim of finding the precise value of aquifer parameters, a new simulation–optimization named MLPG-MTLBO is engaged. Simulation procedure is carried out with meshless local Petrov–Galerkin (MLPG) and optimization model is modified teaching learning-based optimization (MTLBO), a new developed model in this part. These two models are linked to each other and generate an inverse modeling of MLPG-MTLBO for estimation of aquifer parameters. The proposed model will be applied to two aquifers: A standard and a real one.
Materials and methods
In this section, all the methods used for this study explained including optimization algorithm, simulation model, governing equation, and case studies. In optimization stage, MTLBO in the following of TLBO is going to be described, and then, its procedure for optimizing clearly will be expressed. Then, simulation model, MLPG, will be presented in details.
Modify teaching: learning-based optimization (MTLBO) algorithm
A new version of TLBO algorithm (MTBLO) introduced by Hosseinaei et al. (2021) is used as optimization model in this study. In MTLBO, two terms are added in teaching and learning stages of TLBO algorithm. Exploration and exploitation phases also exist in this model (Hosseinaei et al. 2021).
In the stage of exploration, the entire space is examined and at last the region with the best solutions is found. In the stage of exploitation, the mentioned space of previous stage is examined as well. MTLBO similarly of TLBO has teaching and learning phases. One of the differences is that in teaching stage of MTLBO, a term is added. Also, in learning stage, for increasing the speed of searching some technique is applied. These changes are described in the following paragraph.
In the learning phase, for improving the speed of searching for the best response, movement in search space gets smaller and equals to half of the pervious value. Corrections of the TLBO are considered in two stages.
In the learner phases, despite TLBO, movement is toward the best learning (teaching). In addition of that, to improve the speed of students’ learning, running from the worst learner for more space is applied. Therefore, in MTLBO algorithm, firstly, the students are sorted from the worst to the best (teaching). Based on the noted correction, a new term can be added in teaching stage of the TLBO. The modified teaching stage of the TLBO can be determined in Eq. 1 (Hosseinaei et al. 2021):
In this equation, \({X}_{\mathrm{worst}}\) is the worst grade among all the students and TF denotes to the teaching factor.
In the learning stage, a conceptual analysis of TLBO gets clearer which leads to better solutions. In other words, it is considered that a half of the current dimensions (solutions) are changed in the MTLBO.
Meshless local Petrov–Galerkin (MLPG)
Meshless methods due to its independency of meshing have advantageous in comparison with grid-based methods, e.g., FDM and FEM. However, they are in developing stage, they proved their capability in solving partial differential equations. Many scientists used these methods on their work, regardless to its application, whether fluid or solid and reported their results satisfactory and acceptable (Liu and Gu 2005).
The principle of these methods is to enforce the governed equation on some nodes. Nodes are the element which scattered on boundary and the domain. Distance between nodes can be equal and different. You also have the permission to add or remove nodes whenever you need (Liu 2002).
There are many meshless methods for usage. Application of this method is important as well. For example, some meshless methods must be implemented for fluid problems. SPH (smoothed particle hydrodynamic) is one of the fluid meshless methods that applied to rapid flow like surface water. MLPG is another meshless method that is used in our study.
MLPG is usable in both applications, fluid and solid mechanics. It was proposed on 1998 for the first time by Atluri and Zhu (Atluri and Zhu 1998). They developed this method on some studies in 2000 and 2002 as well. MLPG uses two functions in its main body code, weight and shape function. They are determined by W and \(\varnothing\) in the following equations (Mohtashami et al. 2022b).
Governed equation of groundwater flow in confined aquifer
Groundwater flow equation in transient is expressed in Eq. 2 (Dupouit 1863):
where \(H\) is groundwater table (m), \(k\) denotes hydraulic conductivity coefficient (m/s), S is specific storage, \(Q\) indicates the rate of extraction or injection flow in wells (– for extraction wells and + for injection wells) [m/s], and q is precipitation with + sign and evaporation with–sign. \(\delta \left(x-{x}_{w}\right)\left(y-{y}_{w}\right)\) is the Dirac delta function.
After discretization of Eq. 2, \(KU=F\) form of equations is generated as Eqs. 3–5:
\(W\), \(\mathrm{\varnothing }\), \(\Delta t\), \({H}^{(n+1)}\), and \({H}^{(n)}\) are weight function, shape function, time step, groundwater table in the next time step, and groundwater head in the current time step, respectively.
Governed groundwater flow equation in unconfined aquifer
Groundwater flow equation in unsteady state is expressed in Eq. 6 (Wang and Anderson 1995):
where \({S}_{y}\) is specific yield.
As the following equation substituted in Eq. 6:
We have:
With considering the assumption that the aquifer is homogeneous and isotropic (\(k_{x} = k_{y}\)):
\(KU = F\) form of linear equations is generated.
Objective function
In this research, the objective function is defined as the weighted difference between observation and simulation groundwater table in that zone gets minimized. In optimization model, the simulated groundwater table is acquired by MLPG flow model. Also, the objective function is the summation of the weighted squared difference of the observation and simulation groundwater values. The objective function is defined as Eq. 13 (Thomas et al. 2018):
Subject to upper bound and lower bound on parameters
or
or
In this equation, \({h}_{m,t\_Obs}\) and \({h}_{m,t\_Com}\) are the observation and simulation groundwater tables; \({k}_{i}\), \({Sy}_{i}\), and \({T}_{i}\) are the hydraulic conductivity coefficient, specific yield, and transmissivity coefficients at node i; M is the number of piezometers; \({t}_{0}\) and \({t}_{final}\) are starting and ending time of simulation period, \(S\) is the weighted summation of the squares of the differences between the simulated and observed groundwater table, and \({w}_{m,t}\) is a weighting coefficient.
In this study, the weight coefficient is 1. With using MLPG-MTLBO, the objective function and the parameters are computed. Figure 1 shows the flowchart of our work.
The flowchart of the MLPG-MTLBO is drawn in Fig. 1. The model comprises of two simulation and optimization models. MLPG-MTLBO starts from optimization model, the first parameter of optimization algorithm initialized. For computation of objective function, simulation model is started.
Standard aquifer
A confined aquifer, studied in Sharief et al. (2008), is depicted in Fig. 2. Area, thickness, and storage coefficient are 1800*1000 m2, 10 m, and 0.0004, respectively. There are two regions which the aquifer is recharged by them with value of 0.00024 and 0.00012 m/day (Sharief et al. 2008). There are also three extraction wells on the coordinate of (800,200), (800,800), and (1400, 600). The extraction rate from these wells is 200, 500, and 700 m3/day respectively. An injection well is located on (400,800) coordinate and recharges the aquifer with the value of 800 m3/day. The aquifer comprises of three zones. Each zone has different transmissivity coefficient in x and y direction. Boundary conditions for both west and east edges are shown in Fig. 2. North and south sides are impervious as well. Wells located in (600, 400), (1600, 400), and (1000, 600) are determined by observation wells and depicted with blue color.
Real aquifer
Birjand unconfined aquifer which is placed in the east of Iran, South Khorasan province, has 269 km2 area. This aquifer has 190 extraction wells and 10 piezometers. The height of Birjand from the sea is 1491 m. Annual precipitation is 146 mm/year and the average temperature is 16.5 °C. The average thickness of this aquifer is 30 m. Figure 3(a) shows Birjand unconfined aquifer in Iran. In Fig. 3(c), aquifer with its extraction wells (blue symbol) and observation well (red symbols) is determined.
Results and discussion
In order to investigate the capability of proposed model on finding the aquifer parameters, this model was applied on two aquifers, standard and a real aquifer. Standard aquifer is counted as a real case study with simple geometry, known as a good test case for the MLPG-MTLBO model. As noted previously, this aquifer is divided on three zones with different value of T on each direction (\({T}_{x}\ne {T}_{y}\)).
MLPG-MTLBO with the aim of computing aquifer parameters, i.e., transmissivity coefficients on each zone in this problem, is engaged to this aquifer. In the simulation stage, 60 nodes are scattered on the domain and its boundary. These nodes have the same distance to each other exactly 200 m. Following figure shows the scattered nodes. Blue nodes are placed on the boundary and the red nodes are placed on the domain.
Six ranges of transmissivity coefficient are considered for three zones. Three rages relate to transmissivity coefficient in x direction and three ranges are for transmissivity in y direction. Ranges for \({T}_{x}\) in zone 1, 2, and 3 are [400–600], [300–500], and [200–300], respectively. These ranges for \({T}_{y}\) in zone 1, zone 2, and zone 3 are [200–400], [200–300], and [100–300], respectively.
After implementation of the proposed model, transmissivity coefficients are achieved for each zone in each direction. Table 1 shows the computed values against the true values (Fig. 4).
According to the table, estimated values by MLPG-MTLBO have a bit higher accuracy than MLPG-TLBO. This is due to the MTLBO optimization which has some modification on its algorithm. The values of relative error of MLPG-MTLBO present the power of MLPG-MTLBO inverse modeling for estimation of aquifer parameter (Table 2).
As the revealed results of MLPG-MTLBO are satisfactory for standard case, it is applied in the real case. For the real case, Birjand unconfined aquifer was chosen. Nodes with the equal distance of 500 m are placed on the aquifer and its boundary. Boundary of this aquifer is irregular and has its complexity in simulation stage. Node distribution is depicted in Fig. 5. There are 1175 nodes in this aquifer. A total of 110 of them are on the boundary and determined with blue color. For the purpose of parameters estimation, this aquifer is divided to 14 zones. This makes the cost of computation to be lower. All of the 14 zones are depicted with different symbols and colors in Fig. 5.
For this problem, parameter estimation is carried out for finding hydraulic conductivity coefficients and specific yield. These coefficients are mainly determined by pumping tests, but according to the high cost and complicated condition for these tests, few numbers of them are done for Birjand aquifer. Using MLPG-MTLBO makes it simple and computes the parameters in each zone in a way that the objective function arrives to minimum.
Ranges for hydraulic conductivity coefficient and specific yield are [5–65], [0.01–0.5]. These values are chosen due to the values of pumping test results of for 10 pumping wells located in the aquifer based on the report of regional water company of South Khorasan.
MLPG-MTLBO is applied for this aquifer. Implementation is carried out on a home use laptop (Core I5/8 Gb RAM) and MATLAB 2018 programming software. Results are depicted in Fig. 6.
Different colors show different values of hydraulic conductivity coefficients and specific yield in the aquifers. Table 3 presents the estimated hydrodynamic values for all the zones of aquifer.
As you can see hydrodynamic parameters for all zones are estimated. Southwest of aquifer has the least value of hydraulic conductivity coefficient around 2 m/day and zone 6 has the maximum value. Maximum and minimum values of specific yield are for zone 8 and zone 13 respectively.
Groundwater table computed with using the estimated parameters achieved by MLPG-MTLBO. Simulation is carried out for a year with monthly time step. Simulation results for the first and the last period of simulation are presented in the following figures and tables. Observation head is also mentioned in these tables (Tables 4 and 5).
According to the results, some error criteria used in groundwater fields, e.g., RMSE, MSE, and ME, are calculated. The formula of these error criteria is explained in Sadeghi Tabas et al. (2017) research.
Table 6 presents the value of error criteria for FDM, MLPG, and MLPG-MTLBO. Based on this table, MLPG-MTLBO has the highest accuracy, Also MLPG is more accurate than FDM. However, all the three numerical methods reveal satisfactory results, but MLPG-MTLBO has the most reliable groundwater head among them.
RMSE for MLPG-MTLBO is the least value. This fact shows the accuracy of MLPG-MTLBO in estimation of aquifer parameters that leads to results with this accuracy. Following figures indicate computed groundwater head for all twelve months in each piezometer based on the applied numerical method.
These graphs show the results of three different methods in comparison with observation groundwater. Observation graph (orange line) presents the groundwater head where all the results must be compared to it. The blue line indicates MODFLOW head which is based on FDM. All the blue lines have the same trend with observation line. This fact shows the power of FDM in modeling. However, blue lines have distance to observation line in comparison with other lines.
Red line stands for MLPG results which is derived by Mohtashami et al. (2017) research. As it can be seen, MLPG is more accurate than FDM. Trend of MLPG generally does not follow the trend of observation line. For instance, in piezometer 7, MLPG has increasing trend; however, observation line is decreasing. Totally, MLPG is closer than FDM to observation results. It is noticeable that in piezometer 4 in the sixth month due to the high extraction of groundwater in the location of that piezometer, a huge drawdown occurred on the aquifer based on MLPG.
Our proposed model (black line), MLPG-MTLBO, is depicted in Fig. 7. MLPG-MTLBO has the exact trend of observation results. Also, the acquired results by MLPG-MTLBO have the most closeness to observation values. This means the good performance of MLPG-MTLBO model in estimating aquifer parameters leads to high accuracy of groundwater head.
According to the computed groundwater tables for all nodes, 3-dimentional view of aquifer is illustrated in Fig. 8. Groundwater table is higher in the east of aquifer, and it has decreasing value while traveling to the west. At the center of aquifer, as it obvious, due to the dense of extraction wells, drawdown is appeared.
West of the aquifer has the least groundwater head around 1264.45 m.
Conclusion
Understanding the behavior of groundwater system is highly dependent on precise value of aquifer parameters. In order to estimate these parameters, an inverse modeling would be suggested and applied. This study uses simulation–optimization model as an inverse modeling for this purpose. MLPG-MTLBO is S/O model that for parameter estimation, minimized, the summation of the weighted squared difference of the observation and simulation groundwater values. In the most minimization state, aquifer parameters will be derived. MLPG-MTLBO is applied on two aquifers, standard and a real case study. On standard aquifer, transmissivity coefficients for three different zones are computed. The closeness of estimated values to true ones shows the power of this S/O model. Big challenge for this model is the real aquifer. MLPG-MTLBO is engaged on Birjand unconfined aquifer. Hydraulic conductivity coefficients and specific yield are computed for 14 zones of Birjand aquifer. The estimation is too precise that makes the RMSE to reduce from 0.757 to 0.356 m. This means the power of engaged S/O model for this purpose.
Data availability
The datasets used during the current study are available from the corresponding author on reasonable request.
References
Abdelhalim A, Sefelnasr A, Ismail E (2019) Numerical modeling technique for groundwater management in Samalut city, Minia Governorater, Egypt. Arab J Geosci 12(124):1–18
Ansarifar M, Salarijazi M, Ghorbani K, Kaboli AR (2019) Simulation of groundwater level in a coastal aquifer. Mar Georesour Geotechnol 38(3):257–264
Atluri S, Zhu TA (1998) A new meshless method (MLPG) approach in computational mechanics. Comput Mech 22:117–127
Das S, Eldho TI (2022) A meshless weak strong form method for the groundwater flow simulation in an unconfined aquifer. Eng Anal Boundary Elem 137:147–159
Duouit J (1863) Estudes Theoriques et Pratiques sur le Mouvement desEaux. Dunod, Paris
Hosseinaei S, Ghasemi MR, Etedali S (2021) Optimal design of passive and active control systems in seismic-excited structures using a new modified TLBO. Period Polytechn Civ Eng 65(1):37–55
Liu X (2006) Radial point collocation method (RPCM) for solving convection-diffusion problems. J Zhejiang Univ Sci A 7(6):1061–1067
Li J, Chen Y, Darrell P (2003) Radial basis function method for 1-D and 2-D groundwater contaminant transport modeling. Comput Mech 32(1):10–15
Liu G (2002) Mesh free methods: moving beyond the finite element method. CRC Press, Boca Raton
Liu GR, Gu YT (2005) An introduction to meshfree methods and their programming. Springer, Singapore
Majidi N, Mohtashami A, Khorashadeizadeh M, Akbarpour A (2022) Monitoring network design with MLPG-TLBO hybrid model (case study Birjand, Iran). Appl Water Sci 12(6):1–12
Mategaonkar M, Eldho TI (2011) Meshless point collocation method for 1D and 2D groundwater flow simulation. ISH J Hydraul Eng 17(1):71–87
Mategaonkar M, Eldiho TI (2011) Simulation of groundwater flow in unconfined aquifer using meshfree point collocation method. Eng Anal Boundary Elem 35:700–707
Mohtashami A, Akbarpour A, Mollazadeh M (2017) Development of two dimensional groundwater flow simulation model using meshless method based on MLS approximation function in unconfined aquifer in transient state. J Hydroinf 19(5):640–652
Mohtashami A, Hashemin Monfared SA, Azizyan G, Akbarpour A (2021) Estimation of parameters in groundwater modeling by particle filter linked to the meshless local petrov-galerkin numerical method. J Hydraul Struct 7(1):16–37
Mohtashami A, Hashemi Monfared SA, Azizyan G, Akbarpour A (2022a) Application of meshless local petrov-galerkin approach for steady state groundwater flow modeling. Water Supply 22(4):3824–3841
Mohtashami A, Hashemi Monfared SA, Azizyan G, Akbarpour A (2022b) Numerical simulation of groundwater in an unconfined aquifer with a novel hybrid model (case study: Birjand Aquifer, Iran). J Hydroinform 24(1):160–178
Panahi M, Misaghi F, Asgari P (2016) Investigate of groundwater level fluctuations by using GMS. In: 2nd international conference on sustainable development, approaches & challenges with a focus on agriculture, environment and tourism, Tabriz
Pinder G, William G (2013) Finite element simulation in surface and subsurface hydrology. Elsevier, New York
Sadeghitabas S, Samadi SZ, Akbarpour A, Pourreza Bilondi M (2016) Sustainable groundwater modeling using single-and multi-objective optimization algorithms. J Hydroinform 18(5):1–18
Sharief SVM, Eldho TI, Rastgoi AK (2008) Optimal pumping policy for aquifer decontamination by pump and treat method. ISH J Civ Eng 14(2):1–17
Swathi B, Eldho TI (2013) Groundwater flow simulation in confined aquifers using meshless local Petrov-Galerkin. ISH J Hydraul Eng 19:335–348
Swathi B, Eldho TI (2014) Inverse modeling of groundwater system using coupled PSO-MLPG techniques. In: international conference on hydroinformatics, University of New York (CUNY)
Swathi B, Eldho TI (2018) Aquifer parameter and zonation structure estimation using meshless local Petrov-Galerkin method and particle swarm optimization. J Hydroinf 20(2):457–467
Thomas A, Majumdar P, Eldho TI, Rastogi A (2018) Simulation optimization model for aquifer parameter estimation using coupled meshfree point collocation method and cat swarm optimization. Eng Anal Boundary Elem 91:60–72
Thomas A, Eldho TI, Rastogi AK (2012) Ground water flow simulation using meshfree method and fem. In: proceedings of national conference on hydraulics, water resources, coastal and environmental engineering (HYDRO-2012), Bombay, India
Wang HF, Anderson MP (1995) Introduction to groundwater modeling: finite difference and finite element methods. Academic Press, New Jersey, pp 1–12
Author information
Authors and Affiliations
Corresponding author
Ethics declarations
Conflict of interest
The authors declare that they have no conflict of interest.
Consent for publication
This manuscript also does not contain data from any individual person, and therefore, consent to publish is not applicable.
Ethics approval and consent to participate
This manuscript does not report on or involve the use of any animal or human data or tissue.
Additional information
Publisher's Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Sahranavard, H., Mohtashami, A., Mohtashami, E. et al. Inverse modeling application for aquifer parameters estimation using a precise simulation–optimization model. Appl Water Sci 13, 58 (2023). https://doi.org/10.1007/s13201-022-01864-4
Received:
Accepted:
Published:
DOI: https://doi.org/10.1007/s13201-022-01864-4