Abstract
Dynamical systems with intricate behaviour are all-pervasive in biology. Many of the most interesting biological processes indicate the presence of bifurcations, i.e. phenomena where a small change in a system parameter causes qualitatively different behaviour. Bifurcation theory has become a rich field of research in its own right and evaluating the bifurcation behaviour of a given dynamical system can be challenging. An even greater challenge, however, is to learn the bifurcation structure of dynamical systems from data, where the precise model structure is not known. Here, we study one aspects of this problem: the practical implications that the presence of bifurcations has on our ability to infer model parameters and initial conditions from empirical data; we focus on the canonical co-dimension 1 bifurcations and provide a comprehensive analysis of how dynamics, and our ability to infer kinetic parameters are linked. The picture thus emerging is surprisingly nuanced and suggests that identification of the qualitative dynamics—the bifurcation diagram—should precede any attempt at inferring kinetic parameters.
Highlights
Modelling in the physical sciences often proceeds in a rigorous and disciplined manner: a small set of principles is sufficient to develop theoretical models of e.g. molecular dynamics, transport processes in solids or transitions between different phases in condensed matter theory [1]
We investigate dynamical systems modelled by ordinary differential equation (ODE) that undergo bifurcations
We first present the results for the saddle-node bifurcation, before summarizing the results for the three other bifurcations
Summary
Modelling in the physical sciences often proceeds in a rigorous and disciplined manner: a small set of principles is sufficient to develop theoretical models of e.g. molecular dynamics, transport processes in solids or transitions between different phases in condensed matter theory [1]. In many domains, including biology, modelling has to follow a different procedure [3]: for example, if the basic symmetries are too far removed from the processes that we want to model, or the system is too complex (or complicated) to model based on first principles [4]. In these scenarios, we typically have to develop models based on domain expertise and subsequently compare them with available data using e.g. royalsocietypublishing.org/journal/rsos R. Reverse engineering and statistical model selection methods have found widespread use in many disciplines, ranging from engineering and biology to economics and the social sciences [10]
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