TY - UNPB
T1 - On the formulation of size-structured consumer resource models (with special attention for the principle of linearized stability)
AU - Barril, Carles
AU - Calsina, Àngel
AU - Diekmann, Odo
AU - Farkas, Jozsef Z.
PY - 2021/11/18
Y1 - 2021/11/18
N2 - To describe the dynamics of a size-structured population and its unstructured resource, we formulate bookkeeping equations in two different ways. The first, called the PDE formulation, is rather standard. It employs a first order partial differential equation, with a non-local boundary condition, for the size-density of the consumer, coupled to an ordinary differential equation for the resource concentration. The second is called the DELAY formulation and employs a renewal equation for the population level birth rate of the consumer, coupled to a delay differential equation for the (history of the) resource concentration. With each of the two formulations we associate a constructively defined semigroup of nonlinear solution operators. The two semigroups are intertwined by a non-invertible operator. In this paper we delineate in what sense the two semigroups are equivalent. In particular, we i) identify conditions on both the model ingredients and the choice of state space that guarantee that the intertwining operator is surjective, ii) focus on large time behaviour and iii) consider full orbits, i.e., orbits defined for time running from $- \infty $ to $\infty $. For the delay formulation, one can (under certain conditions concerning the model ingredients) prove the differentiability of the solution operators and establish the Principle of Linearised Stability. Next the equivalence of the two formulations yields a rather indirect proof of this principle for the PDE formulation.
AB - To describe the dynamics of a size-structured population and its unstructured resource, we formulate bookkeeping equations in two different ways. The first, called the PDE formulation, is rather standard. It employs a first order partial differential equation, with a non-local boundary condition, for the size-density of the consumer, coupled to an ordinary differential equation for the resource concentration. The second is called the DELAY formulation and employs a renewal equation for the population level birth rate of the consumer, coupled to a delay differential equation for the (history of the) resource concentration. With each of the two formulations we associate a constructively defined semigroup of nonlinear solution operators. The two semigroups are intertwined by a non-invertible operator. In this paper we delineate in what sense the two semigroups are equivalent. In particular, we i) identify conditions on both the model ingredients and the choice of state space that guarantee that the intertwining operator is surjective, ii) focus on large time behaviour and iii) consider full orbits, i.e., orbits defined for time running from $- \infty $ to $\infty $. For the delay formulation, one can (under certain conditions concerning the model ingredients) prove the differentiability of the solution operators and establish the Principle of Linearised Stability. Next the equivalence of the two formulations yields a rather indirect proof of this principle for the PDE formulation.
KW - math.AP
KW - 92D25, 35L04, 34K30
U2 - 10.48550/arXiv.2111.09678
DO - 10.48550/arXiv.2111.09678
M3 - Preprint
SP - 1
EP - 30
BT - On the formulation of size-structured consumer resource models (with special attention for the principle of linearized stability)
PB - arXiv
ER -