Fitting a manifold to data in the presence of large noise

Abstract

We assume that M0 is a d-dimensional C2,1-smooth submanifold of Rn. Let K0 be the convex hull of M0, and Bn1(0) be the unit ball. We assume that M0 ⊂eq ∂ K0 ⊂eq Bn1(0). We also suppose that M0 has volume (d-dimensional Hausdorff measure) less or equal to V, reach (i.e., normal injectivity radius) greater or equal to τ. Moreover, we assume that M0 is R-exposed, that is, tangent to every point x ∈ M there is a closed ball of radius R that contains M. Let x1, …, xN be independent random variables sampled from uniform distribution on M0 and ζ1, …, ζN be a sequence of i.i.d Gaussian random variables in Rn that are independent of x1, …, xN and have mean zero and covariance σ2 In. We assume that we are given the noisy sample points yi, given by yi = xi + ζi, for i = 1, 2, …,N. Let ε,η>0 be real numbers and k≥ 2. Given points yi, i=1,2,…,N, we produce a Ck-smooth function which zero set is a manifold Mrec⊂eq Rn such that the Hausdorff distance between Mrec and M0 is at most ε and Mrec has reach that is bounded below by cτ/d6 with probability at least 1 - η. Assuming d < c n and all the other parameters are positive constants independent of n, the number of the needed arithmetic operations is polynomial in n. In the present work, we allow the noise magnitude σ to be an arbitrarily large constant, thus overcoming a drawback of previous work.

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