Competition and Dispersal in Predator-Prey Waves
Publication date
1998-03-20
Authors
Savill, N.J.
Hogeweg, P.
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Document Type
Article
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Abstract
Dispersing predators and prey can exhibit complex spatio-temporal wave-like patterns if the
interactions between them cause oscillatory dynamics. We study the effect of these predator-
prey density waves on the competition between prey populations and between predator popu-
lations with different dispersal strategies. We first describe 1- and 2-dimensional simulations
of both discrete and continuous predator-prey models. The results suggest that any population
that diffuses faster, disperses farther, or is more likely to disperse will exclude slower diffus-
ing, shorter dispersing, or less likely dispersing populations, everything else being equal. It also
appears that it does not matter whether time, space, or state are discrete or continuous, nor
what the exact interactions between the predators and prey are. So long as waves exist the
competition between populations occurs in a similar fashion. We derive a theory that
qualitatively explains the observed behaviour and calculate approximate analytical solutions
that describe, to a reasonable extent, these behaviours. Predictions about the cost of dispersal
are tested. If strong enough, cost can reverse the populations' relative competitive strengths
or lead to coexistence because of the effect of spiral wave cores. The theory is also able to
explain previous results of simulations of coexistence in host-parasitoid models (Comins,
H. N., and Massell, M. P., 1996, J. Theor. Biol. 183, 19-28).
Keywords
spatial pattern formation, oscillations, individual oriented models, spiral waves, turbulence