Distributional Convergence of the Empirical Laplacians with Integral Kernels on Domains with Boundaries

Abstract

Motivated by the problem of understanding theoretical bounds for the performance of the Belkin-Niyogi Laplacian eigencoordinate approach to dimension reduction in machine learning problems, we consider the convergence of random graph Laplacian operators to a Laplacian-type operator on a manifold. For \Xj\ i.i.d.\ random variables taking values in Rd and K a kernel with suitable integrability we define random graph Laplacians equation* Dε,nf(p)=1nεd+2Σj=1nK(p-Xjε)(f(Xj)-f(p)) equation* and study their convergence as ε=εn0 and n∞ to a second order elliptic operator of the form align* K f(p) &= Σi,j=1d∂ f∂ xi(p)∂ g∂ xj(p)∫RdK(-t)titjdλ(t)\\ & +g(p)2Σi,j=1d∂2f∂ xi∂ xj(p)∫RdK(-t)titjdλ(t). align* Our results provide conditions that guarantee that Dεn,nf(p)-Kf(p) converges to zero in probability as n∞ and can be rescaled by nεnd+2 to satisfy a central limit theorem. They generalize the work of Gin\'e--Koltchinskii~gine2006empirical and Belkin--Niyogi~belkin2008towards to allow manifolds with boundary and a wider choice of kernels K, and to prove convergence under weaker smoothness assumptions and a correspondingly more precise choice of conditions on the asymptotics of εn as n∞.

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