Deterministic computation of quantiles in a Lipschitz framework

Abstract

In this article, we focus on computing the quantiles of a random variable f(X), where X is a [0,1]d-valued random variable, d ∈ N, and f:[0,1]d R is a deterministic Lipschitz function. We are particularly interested in scenarios where the cost of a single function evaluation is high, while the law of X is assumed to be known. In this context, we propose a deterministic algorithm to compute deterministic lower and upper bounds for the quantile of f(X) at a given level α ∈ (0,1). With a fixed budget of N function calls, we demonstrate that our algorithm achieves an exponential deterministic convergence rate for d=1 (O( N) with ∈ (0,1)) and a polynomial deterministic convergence rate for d>1 (O(N-1d-1)) and show the optimality of those rates. Furthermore, we design two algorithms, depending on whether the Lipschitz constant of f is known or unknown.

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