A model for food uptake, energy conversion and allocation is proposed
for individuals that propagate by fission. When simple assumptions for
the environment and interactions between substrate, prey and predator
in a chemostat are made, the conservation laws for energy and biomass
determine a structured population model. This model is compared with
lumped models from the literature, such as the ''Double Monod model''.
Individual-based models consistent with these lumped models, are deri
ved and compared. Expressions for the parameters of the lumped model a
re found as functions of parameters in the model for the individuals m
aking up the population. To reduce the number of parameters body-size
scaling relations are used. The existence and stability of equilibria
under chemostat conditions are studied. The dynamics of the substrate,
bacterial prey and protozoan predator depend substantially on the und
erlying model for the individuals.