A linear-time algorithm computing the resident fitness in interacting trajectories

The notion of a system of interacting trajectories was recently introduced by Hermann, Gonz\'alez Casanova, Soares dos Santos, T\'obi\'as and Wakolbinger. Such a system of $[0,1]$-valued piecewise linear trajectories arises as a scaling limit of the system of logarithmic subpopulation sizes in a certain population-genetic model (more precisely, a Moran model) with mutation and selection. By definition, the resident fitness is initially 0 and afterwards it increases by the ultimate slope of each trajectory that reaches height 1. We show that although the interaction of $n$ trajectories may yield $\Omega(n^2)$ slope changes in total, the resident fitness (at all times) can be computed algorithmically in $O(n)$ time. Our algorithm is given in terms of the so-called continued lines representation of the system of interacting trajectories. In the special case of Poissonian interacting trajectories where the birth times of the trajectories form a Poisson process and the initial slopes are random and i.i.d., we show that even the expected number of slope changes grows only linearly in time.