Implementing machine learning to optimize the cost-benefit of urban water clarifier geometrics
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- @Article{LI:2022:watres,
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author = "Haochen Li and John Sansalone",
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title = "Implementing machine learning to optimize the
cost-benefit of urban water clarifier geometrics",
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journal = "Water Research",
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year = "2022",
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volume = "220",
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pages = "118685",
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keywords = "genetic algorithms, genetic programming, Water
treatment, Green infrastructure, OpenFOAM, PyTorch,
Dakota",
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ISSN = "0043-1354",
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URL = "https://www.sciencedirect.com/science/article/pii/S0043135422006388",
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DOI = "doi:10.1016/j.watres.2022.118685",
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size = "35 pages",
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abstract = "Clarification basins are ubiquitous water treatment
units applied across urban water systems. Diverse
applications include stormwater systems, stabilization
lagoons, equalization, storage and green
infrastructure. Residence time (RT), surface overflow
rate (SOR) and the Storm Water Management Model (SWMM)
are readily implemented but are not formulated to
optimize basin geometrics because transport dynamics
remain unresolved. As a result, basin design yields
high costs from hundreds of thousands to tens of
million USD. Basin optimization and retrofits can
benefit from more robust and efficient tools. More
advanced methods such as computational fluid dynamics
(CFD), while demonstrating benefits for resolving
transport, can be complex and computationally expensive
for routine applications. To provide stakeholders with
an efficient and robust tool, this study develops a
novel optimization framework for basin geometrics with
machine learning (ML). This framework (1) leverages
high-performance computing (HPC) and the predictive
capability of CFD to provide artificial neural network
(ANN) development and (2) integrates a trained ANN
model with a hybrid evolutionary-gradient-based
optimization algorithm through the ANN automatic
differentiation (AD) functionality. ANN model results
for particulate matter (PM) clarification demonstrate
high predictive capability with a coefficient of
determination (R2) of 0.998 on the test dataset. The
ANN model for total PM clarification of three (3)
heterodisperse particle size distributions (PSDs) also
illustrates good performance (R2>0.986). The proposed
framework was implemented for a basin and watershed
loading conditions in Florida (USA), the ML basin
designs yield substantially improved cost-effectiveness
compared to common designs (square and circular basins)
and RT-based design for all PSDs tested. To meet a
presumptive regulatory criteria of 80percent PM
separation (widely adopted in the USA), the ML
framework yields 4.7X to 8X lower cost than the common
basin designs tested. Compared to the RT-based design,
the ML design yields 5.6X to 83.5X cost reduction as a
function of the finer, medium, and coarser PSDs.
Furthermore, the proposed framework benefits from ANN's
high computational efficiency. Optimization of basin
geometrics is performed in minutes on a laptop using
the framework. The framework is a promising adjuvant
tool for cost-effective and sustainable basin
implementation across urban water systems",
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notes = "PMID: 35671685
Department of Civil and Environmental Engineering,
University of Tennessee, Knoxville, Tennessee 37996,
USA",
- }
Genetic Programming entries for
Haochen Li
John J Sansalone
Citations