When can a deterministic model of a population system reveal what will happen on average?
Authored by Leif Gustafsson, Mikael Sternad
Date Published: 2013
DOI: 10.1016/j.mbs.2013.01.006
Sponsors:
No sponsors listed
Platforms:
No platforms listed
Model Documentation:
Other Narrative
Flow charts
Mathematical description
Model Code URLs:
Model code not found
Abstract
A dynamic population system is often modelled by a deterministic
difference equation model to obtain average estimates. However, there is
a risk of the results being distorted because unexplained (random)
variations are left out and because entities in the population are
described by continuous quantities of an infinitely divisible population
so that irregularly occurring events are described by smooth flows.
These distortions have many aspects that cannot be understood by only
regarding a deterministic approach. However, the reasons why a
deterministic model may behave differently and produce biased results
become visible when the deterministic model is compared with a
stochastic model of the same structure.
This paper focuses first on demographic stochasticity, i.e.
stochasticity that refers to random variations in the occurrence of
events affecting the state of an individual, and investigates the
consequences of omitting this by deterministic modelling. These
investigations reveal that bias may be strongly influenced by the type
of question to be answered and by the stopping criterion ending the
analysis or simulation run. Two cases are identified where deterministic
models produce unbiased state variables: (1) Dynamic systems with stable
local linear dynamics produce unbiased state variables asymptotically, in the limit of large flows; and (2) linear dynamic systems produce
unbiased state variables as long as all state variables remain
non-negative in both the deterministic and the stochastic models. Both
cases also require the question under study to be compatible with a
solution over a fixed time interval.
Stochastic variability of initial values between simulation runs because
of uncertainty or lack of information about the initial situation is
denoted initial value stochasticity. Elimination of initial value
stochasticity causes bias unless the model is linear. It may also
considerably enlarge bias from other sources.
Unknown or unexplained variations from the environment (i.e. from
outside the borders of the studied system) enter the model in the form
of stochastic parameters. The omission of this environmental
stochasticity almost always creates biased state variables.
Finally, even when a deterministic model produces unbiased state
variables, the results will be biased if the output functions are not
linear functions of the state variables. (C) 2013 Elsevier Inc. All
rights reserved.
Tags
individual-based models
ecology
Poisson simulation