The approximately ideal, more or less free distribution
Authored by JG Ollason, JM Yearsley
Date Published: 2001
DOI: 10.1006/tpbi.2000.1505
Sponsors:
Community Food Projects (CFP)
European Review of Service Economics and Management (ERSEM)
Platforms:
No platforms listed
Model Documentation:
Other Narrative
Mathematical description
Model Code URLs:
Model code not found
Abstract
We present the minimum set of requirements necessary and sufficient to
represent the foraging behaviour of an animal, and its utilisation of
food, in order to explore the emergent properties of behaviour that
allow animals to reduce their hunger. We present an individual-based
model of foraging that provides a simple quantification of the
requirements, which is sufficiently simple to yield some analytical
results. Complex interactions beyond the scope of analysis have been
explored through simulating animals foraging in regenerating patchy
environments. In most cases the populations pass into equilibrium
distributions which appear to be stable. The equilibria always
approximate closely to the ideal free distribution, although typically
with a small degree of undermatching, (Undermatching is the term applied
to the departure from the ideal free distribution caused by a smaller
proportion of the population than expected occupying areas with a higher
than average regeneration rate). The model therefore implies that the
distribution, 1 hitherto accounted for in terms of ESSs may, in fact, be
simply an effect of the animal's utilization of the food it collects to
reduce its hunger. The model defines a specific feeling rate, v, the
rate at which an animal can feed on a unit of food. This is a function
of three parameters, v(1), the specific feeding rate when alone, v(infinity), the rate, possibly zero, at which it can feed in the
presence of an indefinitely large number of conspecifics, and n(1/2), the number of conspecifics that cause v to take the value ( v(1) +
v(infinity))/2. Exploitation competition in the absence of interference
is represented by setting v(1) = v(infinity). Differences in competitive
ability in exploitation have been represented by simulating animals with
a range of values of v(1), those with the larger values, feeding more
rapidly, being the more effective competitors, and those with the lower
values being the less effective. Interference competition is represented
by setting v(1) > v(infinity) and social facilitation by v(1) <
v(infinity). Individual differences in the strength of interaction are
represented by different values of n(1/2). In competition, the animals
with the larger values of n(1/2) are the more effective competitors: in
facilitation, they are the less effective facilitators. The addition of
physiological and behavioural detail makes very little alteration to the
emergent equilibria, always close to the ideal free distribution, almost
always showing undermatching. (C) 2001 Academic Press.
Tags
Forage