Hardness of Approximation for Shortest Path with Vector Costs

Abstract

We obtain hardness of approximation results for the p-Shortest Path problem, a variant of the classic Shortest Path problem with vector costs. For every integer p ∈ [2,∞), we show a hardness of (p( n / 2 n)1-1/p) for both polynomial- and quasi-polynomial-time approximation algorithms. This nearly matches the approximation factor of O(p( n / n)1-1/p) achieved by a quasi-polynomial-time algorithm of Makarychev, Ovsiankin, and Tani (ICALP 2025). No hardness of approximation results were previously known for any p < ∞. We also present results for the case where p is a function of n. For p = ∞, we establish a hardness of (2 n), improving upon the previous ( n) hardness result. Our result nearly matches the O(2 n) approximation guarantee of the quasi-polynomial-time algorithm by Li, Xu, and Zhang (ICALP 2025). Finally, we present asymptotic bounds on higher-order Bell numbers, which might be of independent interest.

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