Sample Average Approximation for Distributionally Robust Optimization with $\phi$-divergences
Abstract
It is well known that estimating the expectation of any given bounded random variable with values in has a sample complexity of that is independent of the underlying probability measure. We show that this property can no longer hold when evaluating the worst-case expectation of the random variable, where the probability measures defining the expectation belong to a -divergence ball centered at some nominal measure . Specifically, the sample complexity and its dependence on the nominal measure can be completely characterized by the growth of the divergence function. When the divergence function exhibits superlinear growth, a -independent sample complexity can be obtained for sample average approximation, which depends only on the growth of , the radius of the divergence ball, and the target precision. We also provide sample complexity lower bounds and demonstrate the optimality of the obtained bounds for commonly used -divergences. On the other hand, when superlinear growth does not hold for , we show that for any estimation method, evaluating the worst-case expectation has a -dependent sample complexity lower bound that can be made arbitrarily large by changing .
Cite
@article{arxiv.2604.10855,
title = {Sample Average Approximation for Distributionally Robust Optimization with $\phi$-divergences},
author = {Yan Li},
journal= {arXiv preprint arXiv:2604.10855},
year = {2026}
}