A Simple Counting Argument for Dense Linear Hypergraphs
Pith reviewed 2026-06-25 18:58 UTC · model grok-4.3
The pith
A linear r-uniform hypergraph exceeding a quadratic edge threshold contains k edges spanning at most (r-2)k+3 vertices.
A machine-rendered reading of the paper's core claim, the machinery that carries it, and where it could break.
Core claim
For r ≥ 3, k ≥ 3 and n ≥ (r-2)(k-2)+1, every linear r-uniform hypergraph H on n vertices satisfying |E(H)| ≥ ((k-2)/(r²((r-2)(k-2)+1)))n² + n/r contains k edges that together span at most (r-2)k+3 vertices. In the usual linear-density scaling this threshold is asymptotically c ≥ ((r-1)/r)·((k-2)/((r-2)(k-2)+1)) + o(1). The same counting argument recovers the large-uniformity form of the Brown-Erdős-Sós theorem and improves the previous triple-system constant.
What carries the argument
A local averaging argument that counts pairs consisting of an edge and a vertex outside it, using linearity to control pairwise intersections and obtain a global density contradiction.
If this is right
- The asymptotic density threshold is c ≥ ((r-1)/r)·((k-2)/((r-2)(k-2)+1)) + o(1).
- The argument yields a simple proof of the large-uniformity form of the Brown-Erdős-Sós theorem.
- For r=3 the bound improves to c ≥ 2(k-2)/(3(k-1)) + o(1).
- The result holds once n meets or exceeds (r-2)(k-2)+1.
Where Pith is reading between the lines
- The same averaging technique could be tested on hypergraphs that are only approximately linear.
- The explicit constant may be checked for sharpness by constructing random linear hypergraphs for small fixed r and k.
- The method isolates the contribution of linearity, suggesting that removing the linearity hypothesis would require a different counting scheme.
Load-bearing premise
The hypergraph is linear, so any two edges share at most one vertex.
What would settle it
A linear r-uniform hypergraph on sufficiently large n with more than the stated number of edges yet containing no k edges on at most (r-2)k+3 vertices.
read the original abstract
In connection to the Brown-Erd\H{o}s-S\'os conjecture, we give a short local averaging proof of a density theorem for linear uniform hypergraphs. Let $r \ge 3$, $k \ge 3$, and suppose that $n \ge (r-2)(k-2)+1$. If $H$ is a linear $r$-uniform hypergraph on $n$ vertices and \[|E(H)| \geq \frac{k-2}{r^2((r-2)(k-2)+1)}n^2 + \frac{n}{r},\] then $H$ contains $k$ edges spanning at most $(r-2)k+3$ vertices. In the standard linear-density normalization, this gives the asymptotic density threshold $c \geq \frac{r-1}{r} \cdot \frac{k-2}{(r-2)(k-2)+1} + o(1)$. In particular, this yields a simple proof of the large-uniformity form of the Brown-Erd\H{o}s-S\'os theorem, due to Keevash and Long. In the case of triple systems, our bound becomes $c \geq \frac{2(k-2)}{3(k-1)} + o(1)$, improving upon a bound of $\frac{4}{5}$ due to Santos and Tyomkyn.
Editorial analysis
A structured set of objections, weighed in public.
Referee Report
Summary. The manuscript gives a short local averaging proof that any linear r-uniform hypergraph H on n vertices (n ≥ (r-2)(k-2)+1) with |E(H)| ≥ [(k-2)/(r²((r-2)(k-2)+1))]n² + n/r edges must contain k edges spanning at most (r-2)k+3 vertices. In the linear-density normalization this yields the asymptotic threshold c ≥ ((r-1)/r)·((k-2)/((r-2)(k-2)+1)) + o(1). The argument recovers the large-uniformity case of the Brown-Erdős-Sós theorem (Keevash-Long) and improves the r=3 bound from 4/5 to 2(k-2)/(3(k-1)) + o(1).
Significance. If correct, the result supplies an elementary counting proof of an improved density threshold for a configuration central to the Brown-Erdős-Sós conjecture. The proof is short, avoids heavy machinery, and directly improves the best previously published constant for triple systems while also giving a new derivation of the Keevash-Long theorem for large r. These features make the manuscript a useful contribution to extremal hypergraph theory.
minor comments (2)
- §1, after the statement of the main theorem: the phrase 'in the standard linear-density normalization' is used without an explicit definition of the normalization; a one-sentence reminder of the precise scaling would help readers who are not specialists in the area.
- The +n/r additive term in the edge lower bound is retained throughout; the paper should briefly note whether this term can be absorbed into the o(n²) error when only the asymptotic density is required, or whether it is essential for the exact finite-n statement.
Simulated Author's Rebuttal
We thank the referee for their positive assessment of the manuscript and their recommendation to accept.
Circularity Check
No significant circularity identified
full rationale
The paper presents a direct local averaging proof deriving the stated density threshold from the linearity assumption and the given vertex lower bound n ≥ (r-2)(k-2)+1. The threshold constant appears explicitly in the hypothesis and is obtained by counting without parameter fitting, self-definition of the conclusion, or load-bearing self-citations. The argument improves on external prior bounds (Keevash-Long, Santos-Tyomkyn) and remains self-contained against the stated structural hypotheses.
Axiom & Free-Parameter Ledger
axioms (2)
- domain assumption Any two edges intersect in at most one vertex (linearity)
- standard math Standard double counting and averaging inequalities hold over finite sets
Reference graph
Works this paper leans on
-
[1]
W. G. Brown, P. Erd˝ os, and V. T. S´ os,Some extremal problems on r-graphs, New Directions in the Theory of Graphs (Proc. Third Ann. Arbor Conf., Univ. Michigan, Ann Arbor, Mich., 1971), Academic Press, New York, 1973, pp. 53–63
1971
-
[2]
W. G. Brown, P. Erd˝ os, and V. T. S´ os,On the existence of triangulated spheres in 3-graphs, and related problems, Period. Math. Hungar.3(1973), no. 3-4, 221–228
1973
-
[3]
Conlon, L
D. Conlon, L. Gishboliner, Y. Levanzov and A. Shapira, A new bound for the Brown–Erd˝ os–S´ os problem, Journal of Combinatorial Theory, Series B, 158, pp.1-35, 2023
2023
-
[4]
Janzer, A
O. Janzer, A. Methuku, A. Milojevi´ c and B. Sudakov, Power saving for the Brown-Erd˝ os-S´ os problem,Discrete Analysis2025(2025), Paper No. 5, 16 pp
2025
-
[5]
P. Keevash and J. Long,The Brown-Erd˝ os-S´ os conjecture for hypergraphs of large uniformity, arXiv preprint arXiv:2007.14824 (2020). to appear in Proc. Amer. Math. Soc
-
[6]
I. Z. Ruzsa and E. Szemer´ edi, Triple systems with no six points carrying three triangles,Combinatorics (Proc. Fifth Hungarian Colloq., Keszthely, 1976), Vol. II, Colloq. Math. Soc. J´ anos Bolyai18, North-Holland, Amsterdam- New York (1978), 939–945
1976
-
[7]
G. Santos and M. Tyomkyn,The Brown-Erd˝ os-S´ os conjecture in dense triple systems, arXiv preprint arXiv:2508.09841 (2025)
-
[8]
Shapira and M
A. Shapira and M. Tyomkyn, A Ramsey variant of the Brown–Erd˝ os–S´ os conjecture, Bulletin of the London Mathematical Society, 53(5), pp.1453-1469, 2021
2021
-
[9]
Shapira and M
A. Shapira and M. Tyomkyn, A new approach for the Brown-Erd˝ os-S´ os problem, Israel Journal of Mathematics 267(2), pp.717-728, 2025. A SIMPLE COUNTING ARGUMENT FOR DENSE LINEAR HYPERGRAPHS 7 Department of Mathematics, University of Toronto, Toronto, ON, Canada Email address:lior.gishboliner@utoronto.ca Department of Mathematics, University of British Co...
2025
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