Hypergraph removal lemma

In graph theory, the hypergraph removal lemma states that when a hypergraph contains few copies of a given sub-hypergraph, then all of the copies can be eliminated by removing a small number of hyperedges. It is a generalization of the graph removal lemma. The special case in which the graph is a tetrahedron is known as the tetrahedron removal lemma. It was first proved by Nagle, Rödl, Schacht and Skokan[1] and, independently, by Gowers.[2]

The hypergraph removal lemma can be used to prove results such as Szemerédi's theorem[1] and the multi-dimensional Szemerédi theorem.[1]

Statement

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The hypergraph removal lemma states that for any  , there exists   such that for any  -uniform hypergraph   with   vertices the following is true: if   is any  -vertex  -uniform hypergraph with at most   subgraphs isomorphic to  , then it is possible to eliminate all copies of   from   by removing at most   hyperedges from  .

An equivalent formulation is that, for any graph   with   copies of  , we can eliminate all copies of   from   by removing   hyperedges.

Proof idea of the hypergraph removal lemma

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The high level idea of the proof is similar to that of graph removal lemma. We prove a hypergraph version of Szemerédi's regularity lemma (partition hypergraphs into pseudorandom blocks) and a counting lemma (estimate the number of hypergraphs in an appropriate pseudorandom block). The key difficulty in the proof is to define the correct notion of hypergraph regularity. There were multiple attempts[3][4][5][6][7][8][9][10][11][12] to define "partition" and "pseudorandom (regular) blocks" in a hypergraph, but none of them are able to give a strong counting lemma. The first correct definition of Szemerédi's regularity lemma for general hypergraphs is given by Rödl et al.[1]

In Szemerédi's regularity lemma, the partitions are performed on vertices (1-hyperedge) to regulate edges (2-hyperedge). However, for  , if we simply regulate  -hyperedges using only 1-hyperedge, we will lose information of all  -hyperedges in the middle where  , and fail to find a counting lemma.[13] The correct version has to partition  -hyperedges in order to regulate  -hyperedges. To gain more control of the  -hyperedges, we can go a level deeper and partition on  -hyperedges to regulate them, etc. In the end, we will reach a complex structure of regulating hyperedges.

Proof idea for 3-uniform hypergraphs

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For example, we demonstrate an informal 3-hypergraph version of Szemerédi's regularity lemma, first given by Frankl and Rödl.[14] Consider a partition of edges  such that for most triples   there are a lot of triangles on top of   We say that   is "pseudorandom" in the sense that for all subgraphs   with not too few triangles on top of   we have

 
where   denotes the proportion of  -uniform hyperedge in   among all triangles on top of  .

We then subsequently define a regular partition as a partition in which the triples of parts that are not regular constitute at most an   fraction of all triples of parts in the partition.

In addition to this, we need to further regularize   via a partition of the vertex set. As a result, we have the total data of hypergraph regularity as follows:

  1. a partition of   into graphs such that   sits pseudorandomly on top;
  2. a partition of   such that the graphs in (1) are extremely pseudorandom (in a fashion resembling Szemerédi's regularity lemma).

After proving the hypergraph regularity lemma, we can prove a hypergraph counting lemma. The rest of proof proceeds similarly to that of Graph removal lemma.

Proof of Szemerédi's theorem

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Let   be the size of the largest subset of   that does not contain a length   arithmetic progression. Szemerédi's theorem states that,   for any constant  . The high level idea of the proof is that, we construct a hypergraph from a subset without any length   arithmetic progression, then use graph removal lemma to show that this graph cannot have too many hyperedges, which in turn shows that the original subset cannot be too big.

Let   be a subset that does not contain any length   arithmetic progression. Let   be a large enough integer. We can think of   as a subset of  . Clearly, if   doesn't have length   arithmetic progression in  , it also doesn't have length   arithmetic progression in  .

We will construct a  -partite  -uniform hypergraph   from   with parts  , all of which are   element vertex sets indexed by  . For each  , we add a hyperedge among vertices   if and only if   Let   be the complete  -partite  -uniform hypergraph. If  contains an isomorphic copy of   with vertices  , then   for any  . However, note that   is a length   arithmetic progression with common difference  . Since   has no length   arithmetic progression, it must be the case that  , so  .

Thus, for each hyperedge  , we can find a unique copy of   that this edge lies in by finding  . The number of copies of   in   equals  . Therefore, by the hypergraph removal lemma, we can remove   edges to eliminate all copies of   in  . Since every hyperedge of   is in a unique copy of  , to eliminate all copies of   in  , we need to remove at least   edges. Thus,  .

The number of hyperedges in   is  , which concludes that  .

This method usually does not give a good quantitative bound, since the hidden constants in hypergraph removal lemma involves the inverse Ackermann function. For a better quantitive bound, Leng, Sah, and Sawhney proved that   for some constant   depending on  .[15] It is the best bound for   so far.

Applications

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  • The hypergraph removal lemma is used to prove the multidimensional Szemerédi theorem by J. Solymosi.[16] The statement is that any for any finite subset   of  , any   and any   large enough, any subset of   of size at least   contains a subset of the form  , that is, a dilated and translated copy of  . Corners theorem is a special case when  .
  • It is also used to prove the polynomial Szemerédi theorem, the finite field Szemerédi theorem and the finite abelian group Szemerédi theorem.[17][18]

See also

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References

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  1. ^ a b c d Rodl, V.; Nagle, B.; Skokan, J.; Schacht, M.; Kohayakawa, Y. (2005-05-26). "From The Cover: The hypergraph regularity method and its applications". Proceedings of the National Academy of Sciences. 102 (23): 8109–8113. Bibcode:2005PNAS..102.8109R. doi:10.1073/pnas.0502771102. ISSN 0027-8424. PMC 1149431. PMID 15919821.
  2. ^ Gowers, William (2007-11-01). "Hypergraph regularity and the multidimensional Szemerédi theorem". Annals of Mathematics. 166 (3): 897–946. arXiv:0710.3032. Bibcode:2007arXiv0710.3032G. doi:10.4007/annals.2007.166.897. ISSN 0003-486X.
  3. ^ Haviland, Julie; Thomason, Andrew (May 1989). "Pseudo-random hypergraphs". Discrete Mathematics. 75 (1–3): 255–278. doi:10.1016/0012-365x(89)90093-9. ISSN 0012-365X.
  4. ^ Chung, F. R. K.; Graham, R. L. (1989-11-01). "Quasi-random hypergraphs". Proceedings of the National Academy of Sciences. 86 (21): 8175–8177. Bibcode:1989PNAS...86.8175C. doi:10.1073/pnas.86.21.8175. ISSN 0027-8424. PMC 298241. PMID 16594074.
  5. ^ Chung, Fan R. K. (1990). "Quasi-random classes of hypergraphs". Random Structures and Algorithms. 1 (4): 363–382. doi:10.1002/rsa.3240010401. ISSN 1042-9832.
  6. ^ Chung, F. R. K.; Graham, R. L. (1990). "Quasi-random hypergraphs". Random Structures and Algorithms. 1 (1): 105–124. doi:10.1002/rsa.3240010108. ISSN 1042-9832. PMC 298241. PMID 16594074.
  7. ^ Chung, F. R. K.; Graham, R. L. (January 1991). "Quasi-Random Set Systems". Journal of the American Mathematical Society. 4 (1): 151. doi:10.2307/2939258. ISSN 0894-0347. JSTOR 2939258.
  8. ^ Kohayakawa, Yoshiharu; Rödl, Vojtěch; Skokan, Jozef (February 2002). "Hypergraphs, Quasi-randomness, and Conditions for Regularity". Journal of Combinatorial Theory. Series A. 97 (2): 307–352. doi:10.1006/jcta.2001.3217. ISSN 0097-3165.
  9. ^ Frieze, Alan; Kannan, Ravi (1999-02-01). "Quick Approximation to Matrices and Applications". Combinatorica. 19 (2): 175–220. doi:10.1007/s004930050052. ISSN 0209-9683.
  10. ^ Czygrinow, Andrzej; Rödl, Vojtech (January 2000). "An Algorithmic Regularity Lemma for Hypergraphs". SIAM Journal on Computing. 30 (4): 1041–1066. doi:10.1137/s0097539799351729. ISSN 0097-5397.
  11. ^ Chung, Fan R.K. (2007-07-05). "Regularity lemmas for hypergraphs and quasi-randomness". Random Structures & Algorithms. 2 (2): 241–252. doi:10.1002/rsa.3240020208. ISSN 1042-9832.
  12. ^ Frankl, P.; Rödl, V. (December 1992). "The Uniformity Lemma for hypergraphs". Graphs and Combinatorics. 8 (4): 309–312. doi:10.1007/bf02351586. ISSN 0911-0119.
  13. ^ Nagle, Brendan; Rödl, Vojtěch (2003-07-17). "Regularity properties for triple systems". Random Structures & Algorithms. 23 (3): 264–332. doi:10.1002/rsa.10094. ISSN 1042-9832.
  14. ^ Frankl, Peter; Rödl, Vojtěch (2002-02-07). "Extremal problems on set systems". Random Structures & Algorithms. 20 (2): 131–164. doi:10.1002/rsa.10017. ISSN 1042-9832.
  15. ^ Leng, James; Sah, Ashwin; Sawhney, Mehtaab (2024). "Improved Bounds for Szemerédi's Theorem". arXiv:2402.17995.
  16. ^ SOLYMOSI, J. (March 2004). "A Note on a Question of Erdős and Graham". Combinatorics, Probability and Computing. 13 (2): 263–267. doi:10.1017/s0963548303005959. ISSN 0963-5483.
  17. ^ Bergelson, Vitaly; Leibman, Alexander; Ziegler, Tamar (February 2011). "The shifted primes and the multidimensional Szemerédi and polynomial Van der Waerden theorems". Comptes Rendus Mathématique. 349 (3–4): 123–125. arXiv:1007.1839. doi:10.1016/j.crma.2010.11.028. ISSN 1631-073X.
  18. ^ Furstenberg, H.; Katznelson, Y. (December 1991). "A density version of the Hales-Jewett theorem". Journal d'Analyse Mathématique. 57 (1): 64–119. doi:10.1007/bf03041066. ISSN 0021-7670.