Short Second Proof of the Odd-Modulus Directed Torus Hamilton Decomposition Theorem

Abstract

Let Dd(m)=Cay(( Z/m Z)d,\e1,…,ed\), with all generators oriented positively. We give a second proof that Dd(m) decomposes into d directed Hamilton cycles for every d 2 and every odd m 3. The combinatorial core is a fixed-row-sum selection theorem for replicated supports: when each indexed support A is repeated in m identical rows, one can select |A|/2 entries from each row so that every column total is a unit modulo m. Applied to the Hamilton factors using a chosen coordinate direction, these selections prescribe the voltages in a cyclic lift that splits the direction into two. In fibre coordinates, the lifted successor is hj(x,z)=(hj(x),z+ 1\j∈ M(x)\). After one traversal of the base Hamilton cycle, the fibre return is translation by the total carry. Since this carry is a unit modulo m, the return is a single m-cycle and the lifted factor is Hamilton. The new fibres also preserve the direction-constant block structure required for the next split. Iterating from a directed m-cycle with d parallel copies of each arc yields the desired decomposition. The proof strategy was proposed with the assistance of OpenAI GPT-5.5 Pro and formally verified in Lean 4.