Inferring groundwater system dynamics from hydrological time-series data
Created by W.Langdon from
gp-bibliography.bib Revision:1.8129
- @Article{Doglioni:2010:HSJ,
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author = "Angelo Doglioni and Davide Mancarella and
Vincenzo Simeone and Orazio Giustolisi",
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title = "Inferring groundwater system dynamics from
hydrological time-series data",
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journal = "Hydrological Sciences Journal",
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year = "2010",
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volume = "55",
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number = "4",
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pages = "593--608",
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keywords = "genetic algorithms, genetic programming, groundwater,
conceptual model, ordinary differential equations,
evolutionary modelling, shallow aquifer",
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ISSN = "0262-6667",
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URL = "http://www.tandfonline.com/doi/abs/10.1080/02626661003747556",
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DOI = "doi:10.1080/02626661003747556",
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size = "16 pages",
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abstract = "The problem of identifying and reproducing the
hydrological behaviour of groundwater systems can often
be set in terms of ordinary differential equations
relating the inputs and outputs of their physical
components under simplifying assumptions. Conceptual
linear and nonlinear models described as ordinary
differential equations are widely used in hydrology and
can be found in several studies. Groundwater systems
can be described conceptually as an interlinked
reservoir model structured as a series of nonlinear
tanks, so that the groundwater table can be schematised
as the water level in one of the interconnected tanks.
In this work, we propose a methodology for inferring
the dynamics of a groundwater system response to
rainfall, based on recorded time series data. The use
of evolutionary techniques to infer differential
equations from data in order to obtain their intrinsic
phenomenological dynamics has been investigated
recently by a few authors and is referred to as
evolutionary modelling. A strategy named Evolutionary
Polynomial Regression (EPR) has been applied to a real
hydrogeological system, the shallow unconfined aquifer
of Brindisi, southern Italy, for which 528 recorded
monthly data over a 44-year period are available. The
EPR returns a set of non-dominated models, as ordinary
differential equations, reproducing the system
dynamics. The choice of the representative model can be
made both on the basis of its performance against a
test data set and based on its incorporation of terms
that actually entail physical meaning with respect to
the of the system.",
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notes = "In English.",
- }
Genetic Programming entries for
Angelo Doglioni
Davide Mancarella
Vincenzo Simeone
Orazio Giustolisi
Citations