Hamiltonian and Pseudo-Hamiltonian Cycles and Fillings In Simplicial Complexes

Deepak Rajendraprasad; Ilan Newman; Rogers Mathew; Yuri Rabinovich

arxiv: 1907.07907 · v1 · pith:KTRBC5WJnew · submitted 2019-07-18 · 🧮 math.CO

Hamiltonian and Pseudo-Hamiltonian Cycles and Fillings In Simplicial Complexes

Rogers Mathew , Ilan Newman , Yuri Rabinovich , Deepak Rajendraprasad This is my paper

Pith reviewed 2026-05-24 19:58 UTC · model grok-4.3

classification 🧮 math.CO

keywords Hamiltonian cyclessimplicial complexesd-cyclesd-fillingscomplete rankK_n^dboundary operatorconstructive existence

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The pith

Hamiltonian d-cycles of complete rank exist in K_n^d for d=2 on certain n and for d=3 on infinitely many n, with near-Hamiltonian simple d-cycles always constructible.

A machine-rendered reading of the paper's core claim, the machinery that carries it, and where it could break.

The paper defines a Hamiltonian d-cycle in the complete simplicial d-complex on n vertices as a simple d-cycle of complete rank, meaning size exactly 1 plus binom(n-1,d). It fully characterizes the n for which these exist when d equals 2. For d equals 3 it proves existence on infinitely many n. In general it gives explicit constructions of simple d-cycles whose size falls short of the Hamiltonian size by only O(n to the d minus 3). The same statements hold when the objects are replaced by Hamiltonian d-fillings of a given (d-1)-cycle.

Core claim

A Hamiltonian d-cycle in K_n^d is a simple d-cycle of complete rank, or equivalently of size 1 + binom(n-1,d). Over F2 and Q, for d=2 such cycles exist precisely when n meets a stated arithmetic condition. For d=3 they exist for infinitely many n. For every d there exist simple d-cycles of size binom(n-1,d) minus O(n^{d-3}). All statements are proved by explicit constructions. The identical claims hold for Hamiltonian d-fillings, which are acyclic fillings of complete rank; removing one simplex from a Hamiltonian cycle yields a Hamiltonian filling of the boundary of that simplex.

What carries the argument

The Hamiltonian d-cycle (or d-filling), defined as a simple acyclic object of complete rank equivalently sized 1 + binom(n-1,d), whose boundary relation lets removal of one simplex produce a filling of the boundary of that simplex.

If this is right

For d=2 the existence of Hamiltonian 2-cycles is completely characterized by n.
For d=3 Hamiltonian 3-cycles exist on an infinite arithmetic progression of n.
Simple d-cycles of size binom(n-1,d) minus O(n^{d-3}) exist constructively for every d and n.
Hamiltonian d-fillings of any (d-1)-cycle exist under exactly the same conditions as the cycles.
The cycle-to-filling relation holds over both F2 and Q because the boundary of a cycle minus one simplex equals the boundary of the removed simplex.

Where Pith is reading between the lines

These are editorial extensions of the paper, not claims the author makes directly.

The explicit constructions make it feasible to generate the objects by computer for moderate n and check further properties such as link connectivity.
The O(n^{d-3}) gap suggests a natural next question of whether the additive error term can be reduced for each fixed d.
Because the proofs rely only on linear algebra over F2 and Q, analogous statements may hold over any field in which the rank-size equivalence is valid.
These objects supply concrete examples of high-dimensional cycles whose homology is trivial except in the top dimension, useful for testing conjectures on the homology of random complexes.

Load-bearing premise

That complete rank is exactly equivalent to having size 1 + binom(n-1,d) over the coefficient fields F2 and Q, and that the boundary operator acts so a cycle minus one simplex fills the boundary of the removed simplex.

What would settle it

An exhaustive search for n=7 or n=8 and d=2 that finds no Hamiltonian 2-cycle on any of the n predicted by the characterization, or a proof that only finitely many n admit Hamiltonian 3-cycles.

read the original abstract

We introduce and study a $d$-dimensional generalization of Hamiltonian cycles in graphs - the Hamiltonian $d$-cycles in $K_n^d$ (the complete simplicial $d$-complex over a vertex set of size $n$). Those are the simple $d$-cycles of a complete rank, or, equivalently, of size $1 + {{n-1} \choose d}$. The discussion is restricted to the fields $F_2$ and $Q$. For $d=2$, we characterize the $n$'s for which Hamiltonian $2$-cycles exist. For $d=3$ it is shown that Hamiltonian $3$-cycles exist for infinitely many $n$'s. In general, it is shown that there always exist simple $d$-cycles of size ${{n-1} \choose d} - O(n^{d-3})$. All the above results are constructive. Our approach naturally extends to (and in fact, involves) $d$-fillings, generalizing the notion of $T$-joins in graphs. Given a $(d-1)$-cycle $Z^{d-1} \in K_n^d$, ~$F$ is its $d$-filling if $\partial F = Z^{d-1}$. We call a $d$-filling Hamiltonian if it is acyclic and of a complete rank, or, equivalently, is of size ${{n-1} \choose d}$. If a Hamiltonian $d$-cycle $Z$ over $F_2$ contains a $d$-simplex $\sigma$, then $Z\setminus \sigma$ is a a Hamiltonian $d$-filling of $\partial \sigma$ (a closely related fact is also true for cycles over $Q$). Thus, the two notions are closely related. Most of the above results about Hamiltonian $d$-cycles hold for Hamiltonian $d$-fillings as well.

Editorial analysis

A structured set of objections, weighed in public.

Desk editor's note, referee report, simulated authors' rebuttal, and a circularity audit. Tearing a paper down is the easy half of reading it; the pith above is the substance, this is the friction.

Desk Editor's Note private letter to a colleague

Defines Hamiltonian d-cycles via complete rank equated to exact size 1 + binom(n-1,d), with constructive existence for d=2,3 and a general near-maximal bound.

read the letter

The paper's core move is to call a simple d-cycle in the complete complex Hamiltonian when it has complete rank, which they equate to size exactly 1 + binom(n-1,d), and then build some. For d=2 they characterize the n that work. For d=3 they produce them for infinitely many n. In general they construct simple d-cycles of size binom(n-1,d) minus O(n^{d-3}). The same statements hold for the corresponding d-fillings, and they note that dropping one simplex from a cycle over F2 gives a filling of its boundary. All results are presented as constructive and restricted to F2 and Q. That is the actual new content: the size-based definition plus the explicit constructions and the cycle-filling link. The approach is straightforward and extends the T-join idea in a natural way. The load-bearing step is the claimed equivalence between complete rank and that precise size. Every existence result rests on it, so any gap in how the boundary operator or rank is computed over the chosen fields would mean the constructions do not yet establish the Hamiltonian objects. The abstract does not show the derivations, so it is impossible to judge whether the O(n^{d-3}) term is tight or whether edge cases in the size formula are handled. This is for people working on higher-dimensional combinatorial topology or generalizations of Hamiltonicity. A reader who wants explicit constructions rather than existence proofs would find the paper useful. It deserves peer review so that the rank-size equivalence and the boundary arguments can be checked in detail.

Referee Report

2 major / 2 minor

Summary. The paper introduces Hamiltonian d-cycles in the complete simplicial d-complex K_n^d as simple d-cycles of complete rank (equivalently, of size exactly 1 + binom(n-1,d)) over F_2 and Q. It characterizes the n for which such cycles exist when d=2, proves existence for infinitely many n when d=3, and constructs simple d-cycles of size binom(n-1,d) - O(n^{d-3}) in general. Parallel results hold for Hamiltonian d-fillings (acyclic complete-rank fillings of (d-1)-cycles). All results are constructive, and the notions are related by removing one simplex from a cycle to obtain a filling.

Significance. If the rank-size equivalence and boundary-operator properties hold, the constructive existence results generalize Hamiltonian cycles and T-joins to higher dimensions with explicit size bounds, which would be of interest in combinatorial topology.

major comments (2)

[Abstract / §2 (Definitions)] Abstract and definition of Hamiltonian d-cycle: the asserted equivalence between 'complete rank' and size exactly 1 + binom(n-1,d) (and binom(n-1,d) for fillings) is load-bearing for every existence claim. The manuscript must contain an explicit proof that, over F_2 and Q, the boundary map and rank condition on the support imply this precise cardinality; without it the size-based constructions do not establish the claimed complete-rank objects.
[d=3 existence / General construction] § on d=3 infinite family and general O(n^{d-3}) construction: the proofs rely on producing objects of the target size and invoking the equivalence; any gap in the rank-size relation would invalidate the Hamiltonian conclusion for these families.

minor comments (2)

[Abstract] Abstract contains the typo 'a a Hamiltonian'.
[Throughout] Notation for the size formula uses {{n-1} choose d}; consistent LaTeX rendering and explicit definition of the binomial coefficient in the main text would improve readability.

Simulated Author's Rebuttal

2 responses · 0 unresolved

We thank the referee for the careful reading and for highlighting the need for an explicit justification of the rank-size equivalence. We agree this is essential and will add the required proof in the revision.

read point-by-point responses

Referee: [Abstract / §2 (Definitions)] Abstract and definition of Hamiltonian d-cycle: the asserted equivalence between 'complete rank' and size exactly 1 + binom(n-1,d) (and binom(n-1,d) for fillings) is load-bearing for every existence claim. The manuscript must contain an explicit proof that, over F_2 and Q, the boundary map and rank condition on the support imply this precise cardinality; without it the size-based constructions do not establish the claimed complete-rank objects.

Authors: We agree that an explicit proof of the equivalence is required. In the revised manuscript we will insert a new lemma (placed in §2 immediately after the definitions) that proves, over both F_2 and Q, that any simple d-cycle (resp. acyclic d-filling) whose support has full rank in the appropriate chain space must have cardinality exactly 1 + binom(n-1,d) (resp. binom(n-1,d)). The argument uses the exact sequence relating the boundary operator on the complete complex K_n^d to the rank of the support and the fact that the only d-chains of full rank are the ones that span the entire homology or the full cycle space. This lemma will be invoked in all subsequent existence statements. revision: yes
Referee: [d=3 existence / General construction] § on d=3 infinite family and general O(n^{d-3}) construction: the proofs rely on producing objects of the target size and invoking the equivalence; any gap in the rank-size relation would invalidate the Hamiltonian conclusion for these families.

Authors: The constructions in these sections produce objects of the stated cardinalities; once the new lemma establishing the rank-size equivalence is in place, the Hamiltonian (or complete-rank) conclusion follows immediately for the d=3 infinite family and for the general O(n^{d-3}) bound. No further modifications to the constructions themselves are required. revision: yes

Circularity Check

0 steps flagged

No significant circularity; constructions are independent of the size-rank equivalence

full rationale

The paper states the equivalence between 'complete rank' and size 1 + binom(n-1,d) at the definition stage and then supplies explicit constructions that produce objects meeting the size bound. No step reduces a claimed existence result to a fitted parameter, self-citation chain, or definitional renaming; the boundary-operator facts are standard linear-algebra properties over F2/Q. The derivation chain therefore remains self-contained and does not meet any of the enumerated circularity patterns.

Axiom & Free-Parameter Ledger

0 free parameters · 0 axioms · 0 invented entities

Based solely on the abstract, no free parameters, invented entities, or non-standard axioms are visible; the work relies on standard definitions of simplicial complexes, boundary operators, and cycles over F2 and Q.

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discussion (0)

Lean theorems connected to this paper

Citations machine-checked in the Pith Canon. Every link opens the source theorem in the public Lean library.

IndisputableMonolith/Foundation/AlexanderDuality.lean alexander_duality_circle_linking unclear

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unclear
Relation between the paper passage and the cited Recognition theorem.

Those are the simple d-cycles of a complete rank, or, equivalently, of size 1 + binom(n-1,d). ... all maximal acyclic sets have the same size, which is binom(n-1,d)

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supports: The theorem supports part of the paper's argument, but the paper may add assumptions or extra steps.
extends: The paper goes beyond the formal theorem; the theorem is a base layer rather than the whole result.
uses: The paper appears to rely on the theorem as machinery.
contradicts: The paper's claim conflicts with a theorem or certificate in the canon.
unclear: Pith found a possible connection, but the passage is too broad, indirect, or ambiguous to say the theorem truly supports the claim.