Optimal chain density, entropy, and space-time tradeoffs for the TSP
Abstract
We nearly settle a natural extremal question about set systems over [n]: the tradeoff between the size (number of sets) and the number of full chains. This question was initially raised by Johnson, Leader, and Russell [Combin.~Probab.~Comp., 2015] as a counterpart to Sperner-type results in combinatorics. Recently, a framework introduced by Ameli, Nederlof, and Wang, and independently by Dallant and Kozma [FOCS 2026] linked this question to the space- and time-complexity of Bellman-Held-Karp-style dynamic programming algorithms for permutation problems such as the traveling salesman (TSP). Precisely, they showed that a space-time product γn+o(n) is feasible for the TSP, whenever a set system of (normalized) size S and chain density D exists, with γ= S2/D. In this paper we show an essentially optimal bound of γ≈ 3.1819 for this quantity, closing the gap between the previous best lower and upper bounds of γ≥ 3.015 and γ≤ 3.572 respectively. This implies a TSP algorithm with space-time product O(3.1819n) for input size n, as well as a limit to further improvements in this broad framework. More generally, we can obtain close to optimal values D for any feasible value S, effectively settling the question of the number of full chains at every size. The crucial step towards our results is casting the extremal combinatorics question as an information~vs.~entropy tradeoff involving two random variables. This reformulation exactly captures the optimal tradeoff for the combinatorial problem, leading to a framework in which primal-dual certificates can be derived, proving rigorous upper and lower bounds on γ. We also give a further application of our techniques, improving a bound of Duffus, Sands, and Winkler on the minimum size of fibres in the Boolean lattice.
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