Concepts de base
The authors introduce functional input neural networks on weighted spaces, proving global universal approximation results for continuous functions and linear functions of the signature. They rely on Stone-Weierstrass theorems to establish these results.
Résumé
The content discusses the introduction of functional input neural networks on possibly infinite dimensional weighted spaces. By utilizing Stone-Weierstrass theorems, the authors prove global universal approximation results for various types of functions. These results have implications in areas like stochastic analysis and mathematical finance.
The examples provided illustrate how different spaces, such as H¨older spaces, p-variation spaces, and Besov spaces, can be considered as weighted spaces with appropriate weight functions. The concept of admissible weight functions is crucial in defining these spaces and ensuring compactness where necessary.
Overall, the content delves into the theoretical framework of weighted function spaces and their applications in universal approximation theory across various mathematical domains.
Stats
For X = Rd with norm }x} = sqrt(sum(x_i^2)), ψ(x) = η(|x|) where η(r) = exp(βr^γ)
For X being a dual space equipped with weak-* topology, ψ(x) = η(|x|)
For α-H¨older continuous functions x : S Ñ Z, ψ(x) = η(|x|) where |x| denotes the norm in Cα(S; Z)
For α-H¨older continuous paths x : r0, Ts Ñ Z with finite p-variation, ψ(x) = η(|x|)
For Lebesgue-measurable functions x : Rd Ñ R satisfying certain conditions, ψ(x) = η(|x|)
For signed Radon measures x : FΩ Ñ R satisfying certain conditions, ψ(x) = η(||x||)
Citations
"The study of neural networks on finite-dimensional Euclidean spaces was originally initiated by Warren McCulloch and Walter Pitts."
"Our formulation of this weighted Stone-Weierstrass theorem is inspired by Leopoldo Nachbin’s article."
"These UATs on non-compacts are highly relevant in areas like stochastic analysis or mathematical finance."