Distributionally Robust $k$-of-$n$ Sequential Testing
Abstract
The -of- testing problem involves performing independent tests sequentially, in order to determine whether/not at least tests pass. The objective is to minimize the expected cost of testing. This is a fundamental and well-studied stochastic optimization problem. However, a key limitation of this model is that the success/failure probability of each test is assumed to be known precisely. In this paper, we relax this assumption and study a distributionally-robust model for -of- testing. In our setting, each test is associated with an interval that contains its (unknown) failure probability. The goal is to find a solution that minimizes the worst-case expected cost, where each test's probability is chosen from its interval. We focus on non-adaptive solutions, that are specified by a fixed permutation of the tests. When all test costs are unit, we obtain a -approximation algorithm for distributionally-robust -of- testing. For general costs, we obtain an -approximation algorithm on -bounded instances where each uncertainty interval is contained in . We also consider the inner maximization problem for distributionally-robust -of-: this involves finding the worst-case probabilities from the uncertainty intervals for a given solution. For this problem, in addition to the above approximation ratios, we obtain a quasi-polynomial time approximation scheme under the assumption that all costs are polynomially bounded.
Cite
@article{arxiv.2603.23705,
title = {Distributionally Robust $k$-of-$n$ Sequential Testing},
author = {Rayen Tan and Viswanath Nagarajan},
journal= {arXiv preprint arXiv:2603.23705},
year = {2026}
}
Comments
28 pages, 3 figures