Hierarchical threshold structure in Max-Cut with geometric edge weights

Abstract

We study a family of weighted Max-Cut instances on the complete graph Kn in which edge weights decrease geometrically in lexicographic order: the i-th edge has weight rN-i where N=n2. For r 2, the lexicographically first cut is optimal; for r=1, all edges have equal weight and the balanced partition wins. In this paper we study the intermediate regime 1< r <2. The geometric weighting makes early edges dominant and singles out the k-isolated cuts Ck=\1,…,k\\k+1,…,n\ as natural candidates for optimality. For each n and k n/2-1, we define threshold polynomials Pn,k(r) whose unique roots rk(n)∈(1,2) determine when Ck and Ck+1 exchange dominance. We prove that, for fixed n, these thresholds are strictly decreasing in k and that rk(n) 1 as n∞. As our main result, we show that for r∈(rk(n),rk-1(n)) the cut Ck achieves maximum weight among all isolated cuts, yielding a sharp phase diagram for the isolated-cut family. We conjecture that isolated cuts are globally optimal among all 2n-1 cuts when n 7; all counterexamples for small n are characterized completely, and extensive computations for n 100 support the conjecture.

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