Quantitative bounds for high-dimensional non-linear functionals of Gaussian processes
Abstract
In this paper, we establish explicit quantitative Berry-Esseen bounds in the hyper-rectangle distance dR, the convex distance dC and the 1-Wasserstein distance dW for high-dimensional, non-linear functionals of Gaussian processes, allowing for strong dependence between variables. Our main result demonstrates that, under a smoothness assumption, the convergence rate under dR is sub-polynomial in the dimension and polynomial under dC and dW. To the best of our knowledge, our results under dR provide the first explicit sub-polynomial bound for high-dimensional, non-linear functionals of Gaussian processes beyond the i.i.d. setting. Building on this, we derive explicit Berry-Esseen bounds under both dR and dC for multiple statistical examples, such as the method of moments, empirical characteristic functions, empirical moment-generating functions, and functional limit theorems in high-dimensional settings.
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