Overcoming the Curse of Dimensionality in Neural Networks

Abstract

Let A be a set and V a real Hilbert space. Let H be a real Hilbert space of functions f:A V and assume H is continuously embedded in the Banach space of bounded functions. For i=1,·s,n, let (xi,yi)∈ A× V comprise our dataset. Let 0<q<1 and f*∈ H be the unique global minimizer of the functional equation* u(f) = q2 fH2 + 1-q2nΣi=1n f(xi)-yiV2. equation* In this paper we show that for each k∈N there exists a two layer network where the first layer has k functions which are Riesz representations in the Hilbert space H of point evaluation functionals and the second layer is a weighted sum of the first layer, such that the functions fk realized by these networks satisfy equation* fk-f*H2 ≤ ( o(1) + Cq2 E[ DuI(f*)H*2 ] )1k. equation* %Let us note that xi do not need to be in a linear space and yi are in a possibly infinite dimensional Hilbert space V. %The error estimate is independent of the data size n and in the case V is finite dimensional %the error estimate is also independent of the dimension of V. By choosing the Hilbert space H appropriately, the computational complexity of evaluating the Riesz representations of point evaluations might be small and thus the network has low computational complexity.