On Explicit Super-Expressive Approximation for Neural Networks
Abstract
In this work, we investigate the fixed-architecture neural network approximation with explicit parameter bounds and elementary activations. While prior work demonstrated super-expressive approximation using fixed-size networks, they lack quantitative and non-asymptotic characterizations of parameter magnitude with respect to the approximation error. We resolve this issue by introducing the Chinese Remainder Theorem as a constructive encoding mechanism. For Lipschitz continuous functions on [0,1]D, we construct a width-\D,4\, depth-5 network with explicit parameter-error trade-offs. For Hölder-smooth functions in Cr,γA([0,1]D), our fixed network of width \2D,\ D+5N+1\ and depth r + 9 achieves the parameter magnitude P bounded by 2 P=O(-2D/(r+γ)(1/)). This is the dual result compared to those in the parameter-bounded and architecture-unbounded paradigm.
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