We study the stochastic versions of a broad class of combinatorial problems where the weights of the elements in the input data set are uncertain. The class of problems that we study includes shortest paths, minimum weight spanning trees, minimum weight matchings, and other combinatorial problems like knapsack. We observe that the expected value is inadequate in capturing different types of risk-averse or risk-prone behaviors, and, instead, we consider a more general objective, which is to maximize the expected utility of the solution for some given utility function, rather than the expected weight (expected weight becomes a special case). Under the assumption that there is a pseudopolynomial-time algorithm for the exact version of the problem (this is true for the problems mentioned above),(1) we can obtain the following approximation results for several important classes of utility functions: @@@ 1. If the utility function mu is continuous, upper bounded by a constant and mu(x) approaches 0 as x approaches infinity, we show that we can obtain a polynomial-time approximation algorithm with an additive error epsilon for any constant epsilon > 0. @@@ 2. If the utility function mu is a concave increasing function, we can obtain a polynomial-time approximation scheme (PTAS). @@@ 3. If the utility function mu is increasing and has a bounded derivative, we can obtain a PTAS. @@@ Our results recover or generalize several prior results on stochastic shortest-path, stochastic spanning tree, and stochastic knapsack. Our algorithm for utility maximization makes use of the separability of exponential utility and a technique to decompose a general utility function into exponential utility functions, which may be useful in other stochastic optimization problems.

• 出版日期2019-2
• 单位清华大学