Numerical bifurcation analysis of a class of nonlinear renewal equations
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2016
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Abstract
We show, by way of an example, that numerical bifurcation tools for ODE yield reliable bifurcation diagrams when applied to the pseudospectral approximation of a one-parameter family of nonlinear renewal equations. The example resembles logistic-and Ricker-type population equations and exhibits transcritical, Hopf and period doubling bifurcations. The reliability is demonstrated by comparing the results to those obtained by a reduction to a Hamiltonian Kaplan-Yorke system and to those obtained by direct application of collocation methods (the latter also yield estimates for positive Lyapunov exponents in the chaotic regime). We conclude that the methodology described here works well for a class of delay equations for which currently no tailor-made tools exist (and for which it is doubtful that these will ever be constructed).
Keywords
Kaplan-Yorke periodic orbits, Numerical continuation and bifurcation, Period doubling cascade, Pseudospectral and collocation methods, Renewal equations, Stability of periodic solutions, Structured populations, Applied Mathematics
Citation
Breda, D, Diekmann, O, Liessi, D & Scarabel, F 2016, 'Numerical bifurcation analysis of a class of nonlinear renewal equations', Electronic Journal of Qualitative Theory of Differential Equations, vol. 2016, 65. https://doi.org/10.14232/ejqtde.2016.1.65