Transversal Difference Numbers in Finite Abelian Quotients
Pith reviewed 2026-06-29 02:50 UTC · model grok-4.3
The pith
For G=(Z/p²Z)² and H=pG with odd prime p, the transversal difference number δ(G,H) is at least 3p²-p-1 and conjecturally equals (2p-1)².
A machine-rendered reading of the paper's core claim, the machinery that carries it, and where it could break.
Core claim
Transversals T for the quotient in the square-plane case are graphs of functions from F_p² to F_p², and their difference supports D(T) decompose into carry-corrected finite-field derivative images. The authors conjecture that δ(G,H)=(2p-1)² for all odd primes p, prove the unconditional lower bound δ(G,H)≥3p²-p-1, and give small-prime, probabilistic, and fixed-polynomial evidence for the conjecture.
What carries the argument
Decomposition of D(T) into carry-corrected finite-field derivative images for graph transversals from F_p² to F_p²
If this is right
- The general lower bound is achieved precisely when the quotient is cyclic.
- Kneser's theorem produces exact product families when one coordinate is nonsplit cyclic and the remaining factors are arbitrary split.
- The square-plane case is the first genuinely new residual obstruction beyond the general bound.
- If the conjecture holds, then δ(G,H) equals (2p-1)² exactly for every odd prime p.
Where Pith is reading between the lines
- The same decomposition technique could be tested on higher p-powers or other non-cyclic p-adic groups to seek closed-form exact values.
- The connection to small-sumset questions suggests possible direct comparisons with Cauchy-Davenport bounds over finite fields.
- Systematic computation for the next few primes beyond the small cases already checked would provide a direct test of the conjecture.
Load-bearing premise
The decomposition of D(T) into carry-corrected finite-field derivative images for transversals that are graphs of functions F_p² → F_p² fully captures the minimal size without additional hidden relations or overcounting that would invalidate the conjectured exact value.
What would settle it
An explicit transversal T for some odd prime p with |D(T)| smaller than (2p-1)² would falsify the conjecture, while a construction with |D(T)| smaller than 3p²-p-1 would contradict the proven lower bound.
read the original abstract
Given \(H\leq G\) finite abelian groups, a transversal \(T\subseteq G\) for \(G/H\) has fixed size \(|G/H|\), but its ambient difference support \(D(T)=T-T\) can vary with the embedding of \(H\) in \(G\). We call $ \delta(G,H)=\min_T |D(T)| $ the transversal difference number of the pair \((G,H)\). This invariant is related to finite abelian factorisation, tiling complements, and small-sumset questions, and is motivated by recent work regarding ambient Galois labels in CRT transforms for cyclotomic-subfield homomorphic encryption. We prove various results regarding this invariant, including a general lower bound $\delta(G,H)\geq 2|G/H|-m(G,H), $ where \(m(G,H)\) is the largest order of a subgroup of \(G\) disjoint from \(H\). The bound is sharp for cyclic quotients, and Kneser's theorem gives a cross-transversal estimate leading to exact product families with one nonsplit cyclic coordinate and arbitrary split factors. These results isolate the first genuinely new residual obstruction, namely the same-prime square plane \[ G=(\mathbb Z/p^2\mathbb Z)^2,\qquad H=pG. \] For odd \(p\), this case is the technical core of the paper. Here transversals are graphs of functions \(\mathbb F_p^2\to \mathbb F_p^2\), and \(D(T)\) decomposes into carry-corrected finite-field derivative images. We conjecture that \[ \delta(G,H)=(2p-1)^2 \] for all odd primes \(p\), prove the unconditional lower bound \(3p^2-p-1\), and give small-prime, probabilistic, and fixed-polynomial evidence for the conjecture.
Editorial analysis
A structured set of objections, weighed in public.
Referee Report
Summary. The manuscript defines the transversal difference number δ(G,H) as the minimum |D(T)| over transversals T of G/H in finite abelian groups G ⊃ H. It proves the general lower bound δ(G,H) ≥ 2|G/H| − m(G,H) with m(G,H) the largest order of a subgroup of G disjoint from H; shows sharpness for cyclic quotients; obtains exact values for certain product families via Kneser’s theorem; and, for the nonsplit square-plane case G = (ℤ/p²ℤ)², H = pG with odd prime p, conjectures δ(G,H) = (2p−1)², proves the unconditional lower bound δ(G,H) ≥ 3p² − p − 1, and supplies small-prime computational, probabilistic, and fixed-polynomial evidence.
Significance. The general lower bound and its sharpness for cyclic quotients are cleanly established and constitute a solid contribution to difference-set problems in abelian groups. The identification of the square-plane case as the first genuinely new obstruction, together with the explicit modeling via carry-corrected derivatives on graph transversals, isolates a concrete open question whose resolution would have implications for finite abelian factorizations and tiling complements. The computational evidence for small p is a positive feature, though the exact conjecture remains open.
major comments (1)
- [square-plane case section] Square-plane case (abstract and dedicated section): the conjecture δ(G,H) = (2p−1)² is supported by the decomposition of D(T) into carry-corrected finite-field derivative images for graph transversals, yet the manuscript only proves the strictly weaker unconditional bound 3p² − p − 1; it is not shown that the graph representation and carry correction are exhaustive, so hidden additive relations in ℤ/p²ℤ could in principle permit |D(T)| between 3p² − p − 1 and (2p−1)².
minor comments (2)
- [evidence subsection] The phrase 'fixed-polynomial evidence' in the abstract should be expanded in the evidence subsection to specify the precise polynomial family and the range of p for which it was verified.
- [square-plane case section] Notation for the carry-correction map and the finite-field derivative should be introduced with a displayed equation before its first use in the square-plane analysis.
Simulated Author's Rebuttal
We thank the referee for the positive assessment and the recommendation of minor revision. The single major comment is addressed point-by-point below.
read point-by-point responses
-
Referee: [square-plane case section] Square-plane case (abstract and dedicated section): the conjecture δ(G,H) = (2p−1)² is supported by the decomposition of D(T) into carry-corrected finite-field derivative images for graph transversals, yet the manuscript only proves the strictly weaker unconditional bound 3p² − p − 1; it is not shown that the graph representation and carry correction are exhaustive, so hidden additive relations in ℤ/p²ℤ could in principle permit |D(T)| between 3p² − p − 1 and (2p−1)².
Authors: We agree that the manuscript does not contain an explicit lemma proving exhaustiveness of the graph parameterization. Every transversal T for G/H can nevertheless be represented as the graph of a function f: F_p² → F_p² once a fixed section of the quotient map is chosen; the difference set D(T) is then completely determined by the carry-corrected derivatives of f. This follows directly from the coordinate-wise addition law in (ℤ/p²ℤ)², where all carries are explicitly recorded in the model and no further additive relations remain. The unconditional lower bound 3p²−p−1 is derived independently of this parameterization. To remove any ambiguity we will insert a short clarifying lemma establishing that the representation is exhaustive and that the conjecture is therefore posed over the complete set of transversals. revision: yes
Circularity Check
No significant circularity; derivation self-contained
full rationale
The paper defines the new invariant δ(G,H) explicitly as min_T |D(T)| and derives the general lower bound δ(G,H) ≥ 2|G/H| - m(G,H) from subgroup order considerations and Kneser's theorem without reference to the specific (G,H) conjecture. For the square-plane case the conjecture δ(G,H)=(2p-1)^2 is stated as a separate claim, supported by a strictly weaker unconditional bound 3p²-p-1 that is proved independently; the graph-of-functions representation and carry-corrected decomposition are presented as a modeling choice that generates the conjectured value rather than defining it by construction. No load-bearing self-citations, fitted inputs renamed as predictions, or ansätze smuggled via prior work appear in the provided text. The central claims therefore remain independent of their own inputs.
Axiom & Free-Parameter Ledger
axioms (1)
- standard math Kneser's theorem on sumsets in abelian groups
Reference graph
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