The use of Markovian metapopulation models: Reducing the dimensionality of transition matrices by self-organizing Kohonen networks
Authored by EM Griebeler, A Seitz
Date Published: 2006
DOI: 10.1016/j.ecolmodel.2005.06.004
Sponsors:
German Federal Ministry of Education and Research (BMBF)
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Abstract
Markovian population models are used in conservation biology to find an
accurate estimate of a population's extinction probability. Such models
require handling of large transition matrices and calculations are thus
extremely time-consuming when large populations have to be studied. To
accomplish these problems, some authors have suggested to group together
several states/sizes of the population. Unfortunately, this so-called
binning frequently results in errors in estimates obtained. The main
problem with binning is that it assumes that grouped states behave
nearly identical with respect to the underlying stochastic population
process and that so far binning methods implicitly violate this
assumption. In this paper, we present a new binning method based on
self-organizing Kohonen neural networks for time-homogeneous Markovian
metapopulation models. The neural networks are used to analyse one-step
transitions of the Markov chain in order to group only nearly identical
states. We show that the new method is more qualified for the use in
conservation than deterministic methods that we had discussed in a
previous paper (first order Fibonacci binning, pairs binning). It
reveals more accurate and more reliable estimates than these methods.
Errors in estimated extinction probabilities that were introduced by
binning did not exceed one order of magnitude and errors in the global
population size did not exceed 30\%. These errors in estimates
correspond to a low inaccuracy in model parameter values of population
growth and migration ranging from 1 to 10\%. The reduction in the state
space of the studied metapopulations ranged from 21 to 33\% per
subpopulation. The resulting decrease in computing time caused by our
binning method is substantial particularly with regard to simulations
tasks such as comparing the extinction risk of several populations or
performing a detailed sensitivity analysis for model parameters assumed.
The successful estimation of the extinction risk of eight natural
butterfly populations demonstrates the applicability of our new binning
method in conservation biology. A comparison of extinction probabilities
and mean population sizes estimated by Monte Carlo simulations
{[}Griebeler, E.M., Seitz, A., 2002. An individual based model for the
conservation of the endangered Large Blue butterfly, Maculinea arion
(Lepidoptera: Lycaenidae). Ecol. Model. 134, 343-356] with those
obtained from the respective Markov chains for these butterfly
populations revealed similar results on the accuracy of estimates and
the reduction in transition matrices that were predicted by the
comparative error analysis for binning methods. (c) 2005 Elsevier B.V.
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Dynamics
France
Artificial neural-networks