Integrating ecological insight derived from individual-based simulations and physiologically structured population models
Authored by Roger M Nisbet, Benjamin T Martin, Roos Andre M de
Date Published: 2016
DOI: 10.1016/j.ecolmodel.2015.08.013
Sponsors:
European Union
United States National Science Foundation (NSF)
Platforms:
No platforms listed
Model Documentation:
ODD
Mathematical description
Model Code URLs:
Model code not found
Abstract
Two contrasting approaches are widely used to derive population dynamics
as an emergent property deriving from the physiology and behavior of
individual organisms. ``Individual-based models{''} (IBMs) are computer
simulations where the ``state{''} (e.g., age, size) of each individual
in a population is followed explicitly along with changes in its
environment. Population properties (e.g., density, age- or
size-structure) emerge from simple bookkeeping and descriptive
statistics. Physiologically structured population models (PPSMs) have an
identical philosophy, but assume a very large (formally infinite)
population and that all individuals in a given state have an identical
response to any given environment. These assumptions allow the
bookkeeping to proceed through a series of mathematical steps that lead
to partial differential or integral equations describing the population
dynamics. There is software for both approaches that handles the
bookkeeping, with the modeler specifying solely the individual model
using stylized files, thereby eliminating the need for technical
expertise in either complex computer simulations or advanced calculus.
Each approach has its advantages and disadvantages. IBMs are easier to
formulate and to explain to people with limited mathematical experience
than PSPMs, but PSPMs allow for more extensive mapping of possible
dynamic attractors. IBMs alone can reveal the population level effects
of demographic stochasticity and of differences among individuals.
Formal equilibrium analysis of PSPMs show possible stable states (size
distributions) of the populations that include unstable steady states
from which slightly perturbed populations may start cycling. The
equilibrium size structure at these unstable states can serve as an
initial condition for IBMs, thereby facilitating study of the cycles. We
illustrated the interconnections and contrasting insights from the two
approaches using a food-chain model for which the PSPM was previously
studied by De Roos and Persson (Proc. Nat. Acad. Sci. USA: 99, 12907-12912, 2002). Future general population ecology theory requires
work with model populations that are both physiologically structured and
distributed in space. We describe concepts from spatially explicit IBMs
with identical individuals that, in combination with the results in this
paper, may point to a way forward. (C) 2015 Elsevier B.V. All rights
reserved.
Tags
pattern
systems
mobility
Protocol
Size
Predator-prey dynamics
Daphnia
Amplitude cycles
Spatial scale