A parity ErdH{o}s-Hajnal theorem for t-intersecting curves
Pith reviewed 2026-06-27 09:29 UTC · model grok-4.3
The pith
Any large family of t-intersecting blue and green curves contains large subfamilies whose pairwise intersections all share the same parity.
A machine-rendered reading of the paper's core claim, the machinery that carries it, and where it could break.
Core claim
Let B be a set of blue curves and G a set of green curves such that B union G forms a collection of t-intersecting curves in general position. Then there exist subfamilies B prime subset B and G prime subset G with absolute sizes at least epsilon times the sizes of B and G respectively, epsilon positive and depending only on t, such that either every pair from B prime times G prime intersects an even number of times or every such pair intersects an odd number of times.
What carries the argument
Existence of large subfamilies with uniform intersection parity (even or odd) inside any t-intersecting blue-green curve collection.
If this is right
- Any n-vertex topological graph whose edges form a t-intersecting family and contain no k edges that pairwise cross an odd number of times has at most n (log n) to the O_t(log k) edges.
- The statement specializes to the known parity Erdős-Hajnal theorem for pseudo-segments when t equals 1.
- The uniform-parity subfamilies supply a structural dichotomy that can be iterated to obtain quantitative bounds in geometric graph theory.
Where Pith is reading between the lines
- The same parity selection might apply directly to families of curves on surfaces or to higher-dimensional objects with bounded intersection multiplicity.
- One could ask whether the dependence of epsilon on t is polynomial, exponential, or tower-like by constructing explicit lower-bound examples.
- The graph-theoretic consequence suggests analogous bounds for other forbidden odd-crossing configurations in drawings with restricted edge intersections.
Load-bearing premise
The blue and green curves form a t-intersecting family placed in general position.
What would settle it
A single explicit family of t-intersecting curves in the plane whose every sufficiently large blue subset and green subset contains both even-parity and odd-parity crossing pairs.
read the original abstract
For every fixed $t\ge 1$, we prove a parity analogue of the mighty Erd\H{o}s-Hajnal property for $t$-intersecting curves in the plane. Let $\mathcal B$ be a set of blue curves and $\mathcal G$ a set of green curves in the plane such that $\mathcal B\cup\mathcal G$ is a collection of $t$-intersecting curves in general position. We show that there exist subfamilies $\mathcal B'\subseteq\mathcal B$ and $\mathcal G'\subseteq\mathcal G$ such that $|\mathcal B'|\geq \varepsilon|\mathcal B|$ and $|\mathcal G'|\geq \varepsilon|\mathcal G|$, where $\varepsilon>0$ depends only on $t$, such that either every pair in $\mathcal B'\times\mathcal G'$ intersects an even number of times or every such pair intersects an odd number of times. For $t=1$, this recovers the theorem of Fox, Pach, and Suk for pseudo-segments. As an application, we show that every $n$-vertex topological graph with edges forming a $t$-intersecting family and with no $k$ edges that pairwise cross an odd number of times has at most $n(\log n)^{O_t(\log k)}$ edges.
Editorial analysis
A structured set of objections, weighed in public.
Referee Report
Summary. The manuscript proves that for every fixed t ≥ 1, any bichromatic family of t-intersecting curves in general position admits large subfamilies B' and G' such that all pairs from B' × G' have intersections of the same parity (all even or all odd), with the relative size ε > 0 depending only on t. The t = 1 case recovers the Fox–Pach–Suk theorem for pseudo-segments. An application yields an upper bound of n (log n)^{O_t(log k)} on the number of edges in an n-vertex topological graph whose edges form a t-intersecting family and contain no k pairwise odd-crossing edges.
Significance. If correct, the result provides a parity version of the Erdős–Hajnal property in the setting of t-intersecting curves, extending known results for pseudo-segments. The inductive argument via cutting or charging that preserves parity uniformity, together with the exact recovery of the base case and the concrete application to odd-crossing-free topological graphs, constitutes a meaningful advance in extremal combinatorial geometry.
Simulated Author's Rebuttal
We thank the referee for the positive report, the accurate summary of our results, and the recommendation to accept. We are pleased that the significance of the parity Erdős–Hajnal property for t-intersecting curves and its application to topological graphs is recognized.
Circularity Check
No significant circularity; derivation is inductive and externally grounded
full rationale
The paper proves the parity Erdős-Hajnal property for t-intersecting curves by induction on t. The t=1 base case recovers the external theorem of Fox-Pach-Suk on pseudo-segments (no self-citation). The inductive step reduces the t-case to the (t-1)-case via a cutting/charging argument that preserves parity uniformity on large subfamilies, using only the general-position hypothesis to ensure transverse intersections. No equations reduce a claimed prediction to a fitted input by construction, no uniqueness theorems are imported from the authors' prior work, and no ansatz is smuggled via self-citation. The result is self-contained against external benchmarks and does not rely on any of the enumerated circular patterns.
Axiom & Free-Parameter Ledger
axioms (1)
- domain assumption Any two curves intersect at most t times and the whole collection is in general position.
Reference graph
Works this paper leans on
-
[1]
Ackerman, On the maximum number of edges in topological graphs with no four pairwise crossing edges,Discrete Comput
E. Ackerman, On the maximum number of edges in topological graphs with no four pairwise crossing edges,Discrete Comput. Geom.41 (2009), 365–375
2009
-
[2]
Ackerman and G
E. Ackerman and G. Tardos, On the maximum number of edges in quasi-planar graphs,J. Combin. Theory Ser. A114 (2007), 563–571
2007
-
[3]
Fox, A bipartite analogue of Dilworth’s theorem,Order23 (2006), 197–209
J. Fox, A bipartite analogue of Dilworth’s theorem,Order23 (2006), 197–209
2006
-
[4]
J. Fox, J. Pach, and G. Tóth, Intersection patterns of curves,J. London Math. Soc.83 (2011), 389–406
2011
- [5]
-
[6]
J. Fox, J. Pach, and A. Suk, Quasi-planar graphs, string graphs, and the Erdős–Gallai problem, Adv. Math.439 (2024), Paper No. 109501
2024
-
[7]
G. N. Frederickson, Fast algorithms for shortest paths in planar graphs, with applications, SIAM J. Comput.16 (1987), 1004–1022
1987
- [8]
-
[9]
P. N. Klein, S. Mozes, and C. Sommer, Structured recursive separator decompositions for planar graphs in linear time, inProceedings of the 45th ACM Symposium on Theory of Computing, 2013, 505–514
2013
-
[10]
Korándi, J
D. Korándi, J. Pach, and I. Tomon, Large homogeneous submatrices,SIAM J. Discrete Math. 34 (2020), no. 4, 2532–2552
2020
-
[11]
R. J. Lipton and R. E. Tarjan, A separator theorem for planar graphs,SIAM J. Appl. Math. 36 (1979), 177–189
1979
-
[12]
Matoušek,Lectures on Discrete Geometry, Graduate Texts in Mathematics 212, Springer- Verlag, New York, 2002
J. Matoušek,Lectures on Discrete Geometry, Graduate Texts in Mathematics 212, Springer- Verlag, New York, 2002
2002
-
[13]
G. L. Miller, Finding small simple cycle separators for 2-connected planar graphs,J. Comput. System Sci.32 (1986), 265–279
1986
-
[14]
J. Pach, J. Radoičić, and G. Tóth, A generalization of quasi-planarity, inTowards a Theory of Geometric Graphs, Contemp. Math. 342, Amer. Math. Soc., Providence, RI, 2004, 177–183
2004
-
[15]
Pach and J
J. Pach and J. Solymosi, Crossing patterns of segments,J. Combin. Theory Ser. A96 (2001), 316–325
2001
-
[16]
Pach and G
J. Pach and G. Tóth, Disjoint edges in topological graphs, inCombinatorial Geometry and Graph Theory, Lecture Notes in Comput. Sci. 3330, Springer, Berlin, 2005, 133–140
2005
-
[17]
Pach and G
J. Pach and G. Tóth, Comments on Fox News,Geombinatorics15 (2006), 150–154
2006
-
[18]
Thomassen, The Hanani–Tutte theorem,Combinatorica8 (1988), 67–72
C. Thomassen, The Hanani–Tutte theorem,Combinatorica8 (1988), 67–72
1988
-
[19]
Tomon, String graphs have the Erdős–Hajnal property,J
I. Tomon, String graphs have the Erdős–Hajnal property,J. Eur. Math. Soc., to appear. 19
discussion (0)
Sign in with ORCID, Apple, or X to comment. Anyone can read and Pith papers without signing in.