On the generalised ideal flow of closed planar curves

Abstract

For each integer m0 we study the m-ideal energy \[ Em[γ]:=12∫γ ksm2\,ds \] on closed immersed planar curves, where k is signed curvature and s is arclength; k2sm := (ksm)2. The m-ideal energies contain Euler's elastic energy and the Dirichlet energy for the curvature scalar as special cases (m=0,1). We completely classify the closed smooth critical points of Em for all m1: they are precisely the round multiply-covered circles. For the steepest descent L2(ds)-gradient flow of Em, the m-ideal flow, we prove that for each nonzero turning number there is a curvature-oscillation threshold such that every canonical relaxed flow starting from W2,2 initial data below this threshold is immortal and exponentially asymptotic in the smooth topology to a round multiply-covered circle. We also prove that every immortal canonical relaxed trajectory with bounded unnormalised length converges to the corresponding circle. We furthermore treat rough initial data of class W2,2; such data typically has infinite Em energy when m1. In the small-curvature-oscillation basin, every such curve generates a unique canonical relaxed length-normalised flow, smooth for every positive time, continuously dependent on the initial data, and smoothly convergent to the multiply-covered circle. These results are known in the m=0 case, substantially strengthen existing work in the m=1 case, and are new for m>1.