Diagnosis of the artificial intelligence-based predictions of flow regime in a constructed wetland for stormwater pollution control

Abstract Monitoring the velocity field and stage variations in heterogeneous aquatic environments, such as constructed wetlands, is critical for understanding hydrodynamic patterns, nutrient removal capacity, and hydrographic impact on the wetland ecosystem. Obtaining low velocity measurements representative of the entire wetland system may be challenging, expensive, and even infeasible in some cases. Data-driven modeling techniques in the computational intelligence regime may provide fast predictions of the velocity field based on a handful of local measurements. They can be a convenient tool to visualize the general spatial and temporal distribution of flow magnitude and direction with reasonable accurancy in case regular hydraulic models suffer from insufficient baseline information and longer run time. In this paper, a comparison between two types of bio-inspired computational intelligence models including genetic programming (GP) and artificial neural network (ANN) models was implemented to estimate the velocity field within a constructed wetland (i.e., the Stormwater Treatment Area in South Florida) in the Everglades, Florida. Two different ANN-based models, including back propagation algorithm and extreme learning machine, were used. Model calibration and validation were driven by data collected from a local sensor network of Acoustic Doppler Velocimeters (ADVs) and weather stations. In general, the two ANN-based models outperformed the GP model in terms of several indices. Findings may improve the design and operation strategies for similar wetland systems.

[1]  Roberto Battiti,et al.  First- and Second-Order Methods for Learning: Between Steepest Descent and Newton's Method , 1992, Neural Computation.

[2]  Narasimhan Sundararajan,et al.  Classification of Mental Tasks from Eeg Signals Using Extreme Learning Machine , 2006, Int. J. Neural Syst..

[3]  Jing Wang,et al.  The Bounded Capacity of Fuzzy Neural Networks (FNNs) Via a New Fully Connected Neural Fuzzy Inference System (F-CONFIS) With Its Applications , 2014, IEEE Transactions on Fuzzy Systems.

[4]  Chee Kheong Siew,et al.  Extreme learning machine: Theory and applications , 2006, Neurocomputing.

[5]  Holger R. Maier,et al.  Neural networks for the prediction and forecasting of water resource variables: a review of modelling issues and applications , 2000, Environ. Model. Softw..

[6]  James M. Ehrman,et al.  Variations in discharge and dissolved organic carbon and nitrogen export from terrestrial basins with changes in climate: A neural network approach , 1996 .

[7]  Manuel J. Rodríguez,et al.  Assessing empirical linear and non-linear modelling of residual chlorine in urban drinking water systems , 1998, Environ. Model. Softw..

[8]  Guang-Bin Huang,et al.  Upper bounds on the number of hidden neurons in feedforward networks with arbitrary bounded nonlinear activation functions , 1998, IEEE Trans. Neural Networks.

[9]  Luis Puigjaner,et al.  Design optimisation of constructed wetlands for wastewater treatment , 2003 .

[10]  M. Schulz,et al.  The influence of macrophytes on sedimentation and nutrient retention in the lower River Spree (Germany). , 2003, Water research.

[11]  Vladan Babovic,et al.  The evolution of equations from hydraulic data Part II: Applications , 1997 .

[12]  George Tchobanoglous,et al.  Wastewater Engineering Treatment Disposal Reuse , 1972 .

[13]  H. Maier,et al.  The Use of Artificial Neural Networks for the Prediction of Water Quality Parameters , 1996 .

[14]  Shin'ichi Tamura,et al.  Capabilities of a four-layered feedforward neural network: four layers versus three , 1997, IEEE Trans. Neural Networks.

[15]  Vassilios A. Tsihrintzis,et al.  Effect of temperature, HRT, vegetation and porous media on removal efficiency of pilot-scale horizontal subsurface flow constructed wetlands , 2007 .

[16]  Donald A. Hammer,et al.  Constructed Wetlands for Wastewater Treatment , 2020 .

[17]  Vladan Babovic,et al.  Velocity predictions in compound channels with vegetated floodplains using genetic programming , 2003 .

[18]  Sirajuddin Ahmed,et al.  Modelling constructed wetland treatment system performance , 2007 .

[19]  A. Kai Qin,et al.  Evolutionary extreme learning machine , 2005, Pattern Recognit..

[20]  Min Sheng,et al.  Robust Energy Efficiency Maximization in Cognitive Radio Networks: The Worst-Case Optimization Approach , 2015, IEEE Transactions on Communications.

[21]  Vladimir Nikora,et al.  Despiking Acoustic Doppler Velocimeter Data , 2002 .

[22]  Gerald A. Moshiri,et al.  Constructed Wetlands for Water Quality Improvement , 1993 .

[23]  P. Diplas,et al.  Vorticity and circulation: spatial metrics for evaluating flow complexity in stream habitats , 2002 .

[24]  Vladan Babovic,et al.  Emergence, evolution, intelligence; hydroinformatics : a study of distributed and decentralisedcomputing using intelligent agents , 1996 .

[25]  Guang-Bin Huang,et al.  Learning capability and storage capacity of two-hidden-layer feedforward networks , 2003, IEEE Trans. Neural Networks.

[26]  Mohammad Bagher Menhaj,et al.  Training feedforward networks with the Marquardt algorithm , 1994, IEEE Trans. Neural Networks.

[27]  Peter A. Whigham,et al.  Modelling rainfall-runoff using genetic programming , 2001 .

[28]  P. Champion,et al.  The influence of aquatic macrophytes on the hydraulic and physico-chemical properties of a New Zealand lowland stream , 1999, Hydrobiologia.

[29]  A. Gurnell,et al.  Reach‐scale interactions between aquatic plants and physical habitat: River Frome, Dorset , 2006 .

[30]  John R. Koza,et al.  Genetic programming - on the programming of computers by means of natural selection , 1993, Complex adaptive systems.

[31]  Michael T. Manry,et al.  Upper bound on pattern storage in feedforward networks , 2008, Neurocomputing.

[32]  Guang-Bin Huang,et al.  Extreme learning machine: a new learning scheme of feedforward neural networks , 2004, 2004 IEEE International Joint Conference on Neural Networks (IEEE Cat. No.04CH37541).

[33]  M. Bilgili,et al.  Application of artificial neural networks for the wind speed prediction of target station using reference stations data , 2007 .

[34]  Roy A. Armstrong,et al.  Remote sensing characterization of benthic habitats and submerged vegetation biomass in Los Roques Archipelago National Park, Venezuela , 2005 .

[35]  N. Chang,et al.  Integrated data fusion and mining techniques for monitoring total organic carbon concentrations in a lake , 2014 .

[36]  Michael T. Manry,et al.  Upper Bound on Pattern Storage in Feedforward Networks , 2007, 2007 International Joint Conference on Neural Networks.