Physiologically structured models - from versatile technique to ecological theory
Authored by L Persson, Roos AM de
Date Published: 2001
DOI: 10.1034/j.1600-0706.2001.11313.x
Sponsors:
European Union
Netherlands Organization for Scientific Research (NWO)
Platforms:
No platforms listed
Model Documentation:
Other Narrative
Mathematical description
Model Code URLs:
Model code not found
Abstract
A ubiquitous feature of natural communities is the variation in size
that can be observed between organisms, a variation that to a
substantial degree is intraspecific. Size variation within species by
necessity implies that ecological interactions vary both in intensity
and type over the life cycle of an individual. Physiologically
structured population models (PSPMs) constitute a modelling approach
especially designed to analyse these size-dependent interactions as they
explicitly link individual level processes such as consumption and
growth to population dynamics. We discuss two cases where PSPMs have
been used to analyse the dynamics of size-structured populations. In the
first case, a model of a size-structured consumer population feeding on
a non-structured prey was successful in predicting both qualitative
(mechanisms) and quantitative (individual growth. survival, cycle
amplitude) aspects of the population dynamics of a planktivorous fish
population. We conclude that single generation cycles as a result of
intercohort competition is a general outcome of size-structured
consumer-resource interactions. In the second case, involving both
cohort competition and cannibalism, we show that PSPMs may predict
double asymptotic growth trajectories with individuals ending up as
giants. These growth trajectories. which have also been observed in
field data, could not be predicted from individual level information, but are emergent properties of the population feedback on individual
processes. In contrast to the size-structured consumer-resource model, the dynamics in this case cannot be reduced to simpler lumped
stage-based models, but can only be analysed within the domain of PSPMs.
Parameter values used in PSPMs adhere to the individual level and are
derived independently from the system at focus, whereas model
predictions involve both population level processes and individual level
processes under conditions of population feedback. This leads to an
increased ability to test model predictions but also to a larger set of
variables that is predicted at both the individual and population level.
The results turn out to be relatively robust to specific model
assumptions and thus render a higher degree of generality than purely
individual-based models. At the same time. PSPMs offer a much higher
degree of realism, precision and testing ability than lumped stage-based
or non-structured models. The results of our analyses so far suggest
that also in more complex species configurations only a limited set of
mechanisms determines the dynamics of PSPMs. We therefore conclude that
there is a high potential for developing an individual-based, size-dependent community theory using PSPMs.
Tags
community ecology
Predator
Indeterminate growth
Body-size
Population-models
Trophic interactions
Perch perca-fluviatilis
Rutilus-rutilus
Asymmetrical
competition
Prey dynamics