We study a fundamental stochastic selection problem involving n independent random variables, each of which can be queried at some cost. Given a tolerance level, the goal is to find a value that is -approximately minimum (or maximum) over all the random variables, at minimum expected cost. A solution to this problem is an adaptive sequence of queries, where the choice of the next query may depend on previously-observed values. Two variants arise, depending on whether the goal is to find a -minimum value or a -minimizer. When all query costs are uniform, we provide a 4-approximation algorithm for both variants. When query costs are non-uniform, we provide a 5. 83-approximation algorithm for the -minimum value and a 7. 47-approximation for the -minimizer. All our algorithms rely on non-adaptive policies (that perform a fixed sequence of queries), so we also upper bound the corresponding ''adaptivity'' gaps. Our analysis relates the stopping probabilities in the algorithm and optimal policies, where a key step is in proving and using certain stochastic dominance properties.
Al-Thani et al. (Wed,) studied this question.