Reconstruction of Manifold Distances from Noisy Observations

Abstract

We consider the problem of reconstructing the intrinsic geometry of a manifold from noisy pairwise distance observations. Specifically, let M denote a diameter 1 d-dimensional manifold and μ a probability measure on M that is mutually absolutely continuous with the volume measure. Suppose X1,…,XN are i.i.d. samples of μ and we observe noisy-distance random variables d'(Xj, Xk) that are related to the true geodesic distances d(Xj,Xk). With mild assumptions on the distributions and independence of the noisy distances, we develop a new framework for recovering all distances between points in a sufficiently dense subsample of M. Our framework improves on previous work which assumed i.i.d. additive noise with known moments. Our method is based on a new way to estimate L2-norms of certain expectation-functions fx(y)=Ed'(x,y) and use them to build robust clusters centered at points of our sample. Using a new geometric argument, we establish that, under mild geometric assumptions--bounded curvature and positive injectivity radius--these clusters allow one to recover the true distances between points in the sample up to an additive error of O( -1). We develop two distinct algorithms for producing these clusters. The first achieves a sample complexity N -2d-2(1/) and runtime o(N3). The second introduces novel geometric ideas that warrant further investigation. In the presence of missing observations, we show that a quantitative lower bound on sampling probabilities suffices to modify the cluster construction in the first algorithm and extend all recovery guarantees. Our main technical result also elucidates which properties of a manifold are necessary for the distance recovery, which suggests further extension of our techniques to a broader class of metric probability spaces.

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