Abstract
We introduce a higher order phase averaging method for nonlinear oscillatory
systems. Phase averaging is a technique to filter fast motions from the
dynamics whilst still accounting for their effect on the slow dynamics. Phase
averaging is useful for deriving reduced models that can be solved numerically
with more efficiency, since larger timesteps can be taken. Recently, Haut and
Wingate (2014) introduced the idea of computing finite window numerical phase
averages in parallel as the basis for a coarse propagator for a
parallel-in-time algorithm. In this contribution, we provide a framework for
higher order phase averages that aims to better approximate the unaveraged
system whilst still filtering fast motions. Whilst the basic phase average
assumes that the solution independent of changes of phase, the higher order
method expands the phase dependency in a basis which the equations are
projected onto. In this new framework, the original numerical phase averaging
formulation arises as the lowest order version of this expansion. Our new
projection onto functions that are $k$th degree polynomials in the phase gives
rise to higher order corrections to the phase averaging formulation. We
illustrate the properties of this method on an ODE that describes the dynamics
of a swinging spring due to Lynch (2002). Although idealized, this model shows
an interesting analogy to geophysical flows as it exhibits a slow dynamics that
arises through the resonance between fast oscillations. On this example, we
show convergence to the non-averaged (exact) solution with increasing
approximation order also for finite averaging windows. At zeroth order, our
method coincides with a standard phase average, but at higher order it is more
accurate in the sense that solutions of the phase averaged model track the
solutions of the unaveraged equations more accurately.