Nonlinear manifold approximation using compositional polynomial networks

Abstract

We consider the problem of approximating a subset M of a Hilbert space X by a low-dimensional manifold Mn, using samples from M. We propose a nonlinear approximation method where Mn is defined as the range of a smooth nonlinear decoder D defined on Rn with values in a possibly high-dimensional linear space XN, and a linear encoder E which associates to an element from M its coefficients E(u) on a basis of a n-dimensional subspace Xn ⊂ XN, where XN is an optimal or near to optimal linear space, depending on the selected error measure The linearity of the encoder allows to easily obtain the parameters E(u) associated with a given element u in M. The proposed decoder is a polynomial map from Rn to XN which is obtained by a tree-structured composition of polynomial maps, estimated sequentially from samples in M. Rigorous error and stability analyses are provided, as well as an adaptive strategy for constructing the subspace Xn, and a decoder that guarantees an approximation of the set M with controlled mean-squared or wort-case errors, and a controlled stability (Lipschitz continuity) of the encoder and decoder pair. We demonstrate the performance of our method through numerical experiments.

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