INDIVIDUAL-BASED MODELING OF POPULATIONS WITH HIGH MORTALITY - A NEW METHOD BASED ON FOLLOWING A FIXED NUMBER OF MODEL INDIVIDUALS
Authored by Donald L DeAngelis, Kenneth A Rose, SW CHRISTENSEN
Date Published: 1993
DOI: 10.1016/0304-3800(93)90022-k
Sponsors:
United States Department of Energy (DOE)
Electric Power Research Institute (EPRI)
Platforms:
Fortran
Model Documentation:
Other Narrative
Model Code URLs:
Model code not found
Abstract
Individual-based modeling of populations that undergo high mortality can
be problematic. Large numbers of model individuals must be followed to
ensure adequate numbers of survivors at the end of the simulation, but
following large numbers of individuals can require excessive computer
memory and computational time. Following a sample of individuals from
the population partially addresses these problems for short-term
simulations but not for model applications requiring long-term
predictions. In this paper, we describe a resampling algorithm that
permits the long-term simulation of populations undergoing high
mortality. A fixed number of model individuals are followed, with each
representing some number of identical population individuals. As each
model individual dies, a donor individual is randomly selected from the
survivors. The number of population individuals represented by the donor
individual is adjusted to represent the loss of individuals due to
mortality. The dead individual's attributes are then replaced with those
of the donor individual. The high accuracy, reduced memory requirements, and comparable computational costs of the resampling algorithm are
demonstrated using an individual-based population model of
young-of-the-year striped bass. Differences between predictions without
and with resampling were < 1.5\% of the mean values for a suite of
variables. Executable files for versions of the model using resampling
were an order of magnitude smaller, and simulations required similar
computational costs as versions of the model without resampling.
Potential variations of the resampling algorithm to increase the
accuracy of predictions of specific variables and to simulate
spatially-explicit models are discussed.
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