From individuals to population densities: Searching for the intermediate scale of nontrivial determinism
Authored by Simon A Levin, M Pascual
Date Published: 1999
DOI: 10.1890/0012-9658(1999)080[2225:fitpds]2.0.co;2
Sponsors:
United States Department of Energy (DOE)
Andrew Mellon Foundation
Oak Ridge National Laboratory (ORNL)
Platforms:
No platforms listed
Model Documentation:
Other Narrative
Mathematical description
Model Code URLs:
Model code not found
Abstract
The degree of stochasticity or determinism in the dynamics of ecological
systems varies with sampling scale. We propose the application of a
determinism test from nonlinear data analysis to describe this variation
and to identify a characteristic length scale at which to average
spatiotemporal systems. Specifically, we investigate the spatial scale
at which to aggregate individuals into densities in a system that
combines demographic noise with local density-dependent interactions.
The proposed approach is applied to the dynamics of a spatial and
individual-based predator-prey model. The selected spatial scale is
smaller than the one obtained by a previously proposed method whose
similarities and differences we discuss. Two models, the simplest
candidates for approximating the dynamics of densities at the selected
scale, are examined: a predator-prey system of differential equations
that ignores the local nature of the dynamics, and an extension of it
that adds demographic noise. These approximations perform poorly, failing to capture broad statistical features of the predator and prey
fluctuations. These findings indicate that spatial factors are
nonnegligible at the selected intermediate scale of aggregation. Thus, predator-prey systems and other oscillatory ecological systems may
display a dynamic regime at an intermediate scale of aggregation in
which local interactions are still important. We discuss the type of
model needed to approximate population densities in this dynamic regime.
Tags
epidemics
Dynamics
ecosystems
Spatial Models
ecology
pattern
systems
Prediction
Attractors
Chaotic time-series