Random sections of ellipsoids and the power of random information

Abstract

We study the circumradius of the intersection of an m-dimensional ellipsoid E with semi-axes σ1≥…≥ σm with random subspaces of codimension n. We find that, under certain assumptions on σ, this random radius Rn=Rn(σ) is of the same order as the minimal such radius σn+1 with high probability. In other situations Rn is close to the maximum σ1. The random variable Rn naturally corresponds to the worst-case error of the best algorithm based on random information for L2-approximation of functions from a compactly embedded Hilbert space H with unit ball E. In particular, σk is the kth largest singular value of the embedding H L2. In this formulation, one can also consider the case m=∞, and we prove that random information behaves very differently depending on whether σ ∈ 2 or not. For σ 2 random information is completely useless, i.e., E[Rn] = σ1. For σ ∈ 2 the expected radius of random information tends to zero at least at rate o(1/n) as n∞. In the important case σk k-α -β(k+1), where α > 0 and β∈ R, we obtain that E [Rn(σ)] cases σ1 & : α<1/2 \, or \, β≤α=1/2 \\ σn \, (n+1) & : β>α=1/2 \\ σn+1 & : α>1/2. cases In the proofs we use a comparison result for Gaussian processes \`a la Gordon, exponential estimates for sums of chi-squared random variables, and estimates for the extreme singular values of (structured) Gaussian random matrices. The upper bound is constructive. It is proven for the worst case error of a least squares estimator.