Posterior Contraction and Credible Sets for Filaments of Regression Functions

03/11/2018
by   Wei Li, et al.
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A filament consists of local maximizers of a smooth function f when moving in a certain direction. Filamentary structures are important features of the shape of objects and are also considered as important lower dimensional characterization of multivariate data. There have been some recent theoretical studies of filaments in the nonparametric kernel density estimation context. This paper supplements the current literature in two ways. First, we provide a Bayesian approach to the filament estimation in regression context and study the posterior contraction rates using a finite random series of B-splines basis. Compared with the kernel-estimation method, this has theoretical advantage as the bias can be better controlled when the function is smoother, which allows obtaining better rates. Assuming that f: R^2 R belongs to an isotropic Hölder class of order α≥ 4, with the optimal choice of smoothing parameters, the posterior contraction rates for the filament points on some appropriately defined integral curves and for the Hausdorff distance of the filament are both (n/ n)^(2-α)/(2(1+α)). Secondly, we provide a way to construct a credible set with sufficient frequentist coverage for the filaments. Our valid credible region consists of posterior filaments that have frequentist interpretation. We demonstrate the success of our proposed method in simulations and application to earthquake data.

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