Pattern-oriented modeling of bird foraging and pest control in coffee farms
Authored by Steven F Railsback, Matthew D Johnson
Date Published: 2011
DOI: 10.1016/j.ecolmodel.2011.07.009
Sponsors:
United States National Science Foundation (NSF)
Platforms:
NetLogo
Model Documentation:
ODD
Flow charts
Model Code URLs:
Model code not found
Abstract
We develop a model of how land use and habitat diversity affect
migratory bird populations and their ability to suppress an insect pest
on Jamaican coffee farms. Bird foraging-choosing which habitat patch and
prey to use as prey abundance changes over space and time-is the key
process driving this system. Following the ``pattern-oriented{''}
modeling strategy, we identified nine observed patterns that
characterize the real system's dynamics. The model was designed so that
these patterns could potentially emerge from it. The resulting model is
individual-based, has fine spatial and temporal resolutions, represents
very simply the supply of the pest insect and other arthropod food in
six habitat types, and includes foraging habitat selection as the only
adaptive behavior of birds. Although there is an extensive heritage of
bird foraging theory in ecology, most of it addresses only the
individual level and is too simple for our context. We used
pattern-oriented modeling to develop and test foraging theory for this
across-scale problem: rules for individual bird foraging that cause the
model to reproduce a variety of patterns observed at the system level.
Four alternative foraging theories were contrasted by how well they
caused the model to reproduce the nine characteristic patterns. Four of
these patterns were clearly reproduced with the ``null{''} theory that
birds select habitat randomly. A version of classical theory in which
birds stay in a patch until food is depleted to some threshold caused
the model to reproduce five patterns; this theory caused lower, not
higher, use of habitat experiencing an outbreak of prey insects.
Assuming that birds select the nearby patch providing highest intake
rate caused the model to reproduce all but one pattern, whereas assuming
birds select the highest-intake patch over a large radius produced an
unrealistic distribution of movement distances. The pattern reproduced
under none of the theories, a negative relation between bird density and
distance to trees, appears to result from a process not in the model:
birds return to trees at night to roost. We conclude that a foraging
model for small insectivorous birds in diverse habitat should assume
birds can sense higher food supply but over short, not long, distances.
(C) 2011 Elsevier B.V. All rights reserved.
Tags
Individual-based model
Conservation
Habitats
Services
Functional-response
Tests
Hypothenemus-hampei coleoptera
Berry borer
Farmland bird
Scolytidae