Unrestricted iterations of relaxed projections in Hilbert space: Regularity, absolute convergence, and statistics of displacements

Abstract

Given a finite collection V:=(V1,…,VN) of closed linear subspaces of a real Hilbert space H, let Pi denote the orthogonal projection operator onto Vi and Pi,λ:= (1-λ)I + λ Pi denote its relaxation with parameter λ ∈ [0,2], i=1,…,N. Under a mild regularity assumption on V known as `innate regularity' (which, for example, is always satisfied if each Vi has finite dimension or codimension), we show that all trajectories (xn)0∞ resulting from the iteration xn+1 := Pin,λn(xn), where the in and the λn are unrestricted other than the assumption that \λn : n ∈ N\ ⊂ [η,2-η] for some η ∈ (0,1], possess uniformly bounded displacement moments of arbitrarily small orders. In particular, we show that Σn=0∞ \|xn+1 - xn \|γ ≤ C \|x0\|γ ~ for all ~ γ > 0, where C:=C(V,η,γ)<∞. This result strengthens prior results on norm convergence of these trajectories, known to hold under the same regularity assumption. For example, with γ=1, it follows that the displacements series Σ (xn+1-xn) converges absolutely in H. Quantifying the constant C(V,η,γ), we also derive an effective bound on the distribution function of the norms of the displacements (normalized by the norm of the initial condition) which yields a root-exponential type decay bound on their decreasing rearrangement, again uniformly for all trajectories.