Short Second Proof of the Odd-Modulus Directed Torus Hamilton Decomposition Theorem
Pith reviewed 2026-06-26 13:35 UTC · model grok-4.3
The pith
The directed Cayley graph D_d(m) on (Z/mZ)^d decomposes into d directed Hamilton cycles for every d≥2 and odd m≥3.
A machine-rendered reading of the paper's core claim, the machinery that carries it, and where it could break.
Core claim
D_d(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 floor(|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 ĥ_j(x,z)=(h_j(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
What carries the argument
The fixed-row-sum selection theorem for replicated supports, which selects floor(|A|/2) entries per row so every column sum is a unit modulo m, controlling the carry in each cyclic lift.
If this is right
- Each application of the selection theorem produces a valid Hamilton factor whose fibres remain direction-constant blocks.
- Starting from d parallel copies of a directed m-cycle and iterating the lift d-1 times produces the full decomposition.
- The same selection mechanism works uniformly for every coordinate direction chosen at each splitting step.
- The resulting factors are edge-disjoint and cover every arc exactly once.
Where Pith is reading between the lines
- The same selection theorem might allow decompositions when m is even if the unit condition is relaxed to coprime carries.
- The block-preservation property could extend the method to other Cayley graphs on abelian groups with similar generating sets.
- Formal verification in Lean 4 confirms that the combinatorial steps contain no hidden case distinctions for the given parameter ranges.
Load-bearing premise
The fixed-row-sum selection theorem holds when each support is replicated across m identical rows.
What would settle it
An explicit counterexample to the selection theorem for some support size and odd m, or a pair (d,m) with odd m≥3 where D_d(m) admits no decomposition into d directed Hamilton cycles.
read the original abstract
Let $D_d(m)=\operatorname{Cay}((\mathbb Z/m\mathbb Z)^d,\{e_1,\ldots,e_d\})$, with all generators oriented positively. We give a second proof that $D_d(m)$ decomposes into $d$ directed Hamilton cycles for every $d\ge 2$ and every odd $m\ge 3$. 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 $\lfloor |A|/2\rfloor$ 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 $\widehat h_j(x,z)=(h_j(x),z+\mathbf 1_{\{j\in M(x)\}})$. 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.
Editorial analysis
A structured set of objections, weighed in public.
Referee Report
Summary. The paper gives a second proof that the directed Cayley graph D_d(m) = Cay((Z/mZ)^d, {e1,...,ed}) with all generators oriented positively decomposes into d directed Hamilton cycles whenever d≥2 and m≥3 is odd. The argument proceeds by iterative cyclic lifting: a fixed-row-sum selection theorem for m replicated copies of each support A is used to choose voltages so that each lifted factor remains Hamilton (the fibre return is a single m-cycle because the total carry is a unit mod m), while preserving the block structure needed for the next split. The base case begins with d parallel copies of a directed m-cycle; the entire construction, including the selection theorem, is formally verified in Lean 4.
Significance. If correct, the result supplies an alternative combinatorial proof of the odd-modulus directed torus Hamilton decomposition. The explicit machine-checked verification in Lean 4 of the selection theorem and the lifting steps constitutes independent, reproducible support for the central combinatorial core and is a notable strength of the manuscript.
minor comments (1)
- The abstract states that the proof strategy was proposed with assistance from OpenAI GPT-5.5 Pro; while not affecting correctness, a brief clarification in the introduction on the precise division of labor between the AI suggestion and the subsequent Lean formalization would improve transparency.
Simulated Author's Rebuttal
We thank the referee for their positive summary, recognition of the significance of the combinatorial argument and Lean 4 verification, and recommendation to accept the manuscript.
Circularity Check
No significant circularity
full rationale
The manuscript supplies an explicit combinatorial argument whose core is the fixed-row-sum selection theorem, together with an iterative voltage-lifting construction whose correctness is asserted to have been machine-checked in Lean 4. Machine-checked proofs count as independent external support under the evaluation rules; the derivation therefore does not reduce to any fitted parameter, self-definitional equation, or load-bearing self-citation chain. No instance of the six enumerated circularity patterns appears in the provided text.
Axiom & Free-Parameter Ledger
axioms (1)
- domain assumption Fixed-row-sum selection theorem for replicated supports holds
Reference graph
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discussion (0)
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