A direct approach for function approximation on data defined manifolds
Hrushikesh Mhaskar

TL;DR
This paper introduces a direct, training-free method for approximating functions on unknown data manifolds, avoiding eigen-decomposition or atlas construction, and providing universal, smooth function approximation guarantees.
Contribution
It proposes a novel direct approach for function approximation on unknown manifolds that does not rely on eigen-decomposition or local charts, unlike traditional methods.
Findings
Method is universal and does not require prior knowledge of the target function.
Approximation estimates do not suffer from saturation for smooth functions.
Results can be extended to deep networks with Gaussian channels on manifolds.
Abstract
In much of the literature on function approximation by deep networks, the function is assumed to be defined on some known domain, such as a cube or a sphere. In practice, the data might not be dense on these domains, and therefore, the approximation theory results are observed to be too conservative. In manifold learning, one assumes instead that the data is sampled from an unknown manifold; i.e., the manifold is defined by the data itself. Function approximation on this unknown manifold is then a two stage procedure: first, one approximates the Laplace-Beltrami operator (and its eigen-decomposition) on this manifold using a graph Laplacian, and next, approximates the target function using the eigen-functions. Alternatively, one estimates first some atlas on the manifold and then uses local approximation techniques based on the local coordinate charts. In this paper, we propose a more…
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