In additive combinatorics, a discipline within mathematics, Freiman's theorem is a central result which indicates the approximate structure of sets whose sumset is small. It roughly states that if is small, then can be contained in a small generalized arithmetic progression.

Statement

edit

If   is a finite subset of   with  , then   is contained in a generalized arithmetic progression of dimension at most   and size at most  , where   and   are constants depending only on  .

Examples

edit

For a finite set   of integers, it is always true that

 

with equality precisely when   is an arithmetic progression.

More generally, suppose   is a subset of a finite proper generalized arithmetic progression   of dimension   such that   for some real  . Then  , so that

 

History of Freiman's theorem

edit

This result is due to Gregory Freiman (1964, 1966).[1][2][3] Much interest in it, and applications, stemmed from a new proof by Imre Z. Ruzsa (1992,1994).[4][5] Mei-Chu Chang proved new polynomial estimates for the size of arithmetic progressions arising in the theorem in 2002.[6] The current best bounds were provided by Tom Sanders.[7]

Tools used in the proof

edit

The proof presented here follows the proof in Yufei Zhao's lecture notes.[8]

Plünnecke–Ruzsa inequality

edit

Ruzsa covering lemma

edit

The Ruzsa covering lemma states the following:

Let   and   be finite subsets of an abelian group with   nonempty, and let   be a positive real number. Then if  , there is a subset   of   with at most   elements such that  .

This lemma provides a bound on how many copies of   one needs to cover  , hence the name. The proof is essentially a greedy algorithm:

Proof: Let   be a maximal subset of   such that the sets   for   are all disjoint. Then  , and also  , so  . Furthermore, for any  , there is some   such that   intersects  , as otherwise adding   to   contradicts the maximality of  . Thus  , so  .

Freiman homomorphisms and the Ruzsa modeling lemma

edit

Let   be a positive integer, and   and   be abelian groups. Let   and  . A map   is a Freiman  -homomorphism if

 

whenever   for any  .

If in addition   is a bijection and   is a Freiman  -homomorphism, then   is a Freiman  -isomorphism.

If   is a Freiman  -homomorphism, then   is a Freiman  -homomorphism for any positive integer   such that  .

Then the Ruzsa modeling lemma states the following:

Let   be a finite set of integers, and let   be a positive integer. Let   be a positive integer such that  . Then there exists a subset   of   with cardinality at least   such that   is Freiman  -isomorphic to a subset of  .

The last statement means there exists some Freiman  -homomorphism between the two subsets.

Proof sketch: Choose a prime   sufficiently large such that the modulo-  reduction map   is a Freiman  -isomorphism from   to its image in  . Let   be the lifting map that takes each member of   to its unique representative in  . For nonzero  , let   be the multiplication by   map, which is a Freiman  -isomorphism. Let   be the image  . Choose a suitable subset   of   with cardinality at least   such that the restriction of   to   is a Freiman  -isomorphism onto its image, and let   be the preimage of   under  . Then the restriction of   to   is a Freiman  -isomorphism onto its image  . Lastly, there exists some choice of nonzero   such that the restriction of the modulo-  reduction   to   is a Freiman  -isomorphism onto its image. The result follows after composing this map with the earlier Freiman  -isomorphism.

Bohr sets and Bogolyubov's lemma

edit

Though Freiman's theorem applies to sets of integers, the Ruzsa modeling lemma allows one to model sets of integers as subsets of finite cyclic groups. So it is useful to first work in the setting of a finite field, and then generalize results to the integers. The following lemma was proved by Bogolyubov:

Let   and let  . Then   contains a subspace of   of dimension at least  .

Generalizing this lemma to arbitrary cyclic groups requires an analogous notion to “subspace”: that of the Bohr set. Let   be a subset of   where   is a prime. The Bohr set of dimension   and width   is

 

where   is the distance from   to the nearest integer. The following lemma generalizes Bogolyubov's lemma:

Let   and  . Then   contains a Bohr set of dimension at most   and width  .

Here the dimension of a Bohr set is analogous to the codimension of a set in  . The proof of the lemma involves Fourier-analytic methods. The following proposition relates Bohr sets back to generalized arithmetic progressions, eventually leading to the proof of Freiman's theorem.

Let   be a Bohr set in   of dimension   and width  . Then   contains a proper generalized arithmetic progression of dimension at most   and size at least  .

The proof of this proposition uses Minkowski's theorem, a fundamental result in geometry of numbers.

Proof

edit

By the Plünnecke–Ruzsa inequality,  . By Bertrand's postulate, there exists a prime   such that  . By the Ruzsa modeling lemma, there exists a subset   of   of cardinality at least   such that   is Freiman 8-isomorphic to a subset  .

By the generalization of Bogolyubov's lemma,   contains a proper generalized arithmetic progression of dimension   at most   and size at least  . Because   and   are Freiman 8-isomorphic,   and   are Freiman 2-isomorphic. Then the image under the 2-isomorphism of the proper generalized arithmetic progression in   is a proper generalized arithmetic progression in   called  .

But  , since  . Thus

 

so by the Ruzsa covering lemma   for some   of cardinality at most  . Then   is contained in a generalized arithmetic progression of dimension   and size at most  , completing the proof.

Generalizations

edit

A result due to Ben Green and Imre Ruzsa generalized Freiman's theorem to arbitrary abelian groups. They used an analogous notion to generalized arithmetic progressions, which they called coset progressions. A coset progression of an abelian group   is a set   for a proper generalized arithmetic progression   and a subgroup   of  . The dimension of this coset progression is defined to be the dimension of  , and its size is defined to be the cardinality of the whole set. Green and Ruzsa showed the following:

Let   be a finite set in an abelian group   such that  . Then   is contained in a coset progression of dimension at most   and size at most  , where   and   are functions of   that are independent of  .

Green and Ruzsa provided upper bounds of   and   for some absolute constant  .[9]

Terence Tao (2010) also generalized Freiman's theorem to solvable groups of bounded derived length.[10]

Extending Freiman’s theorem to an arbitrary nonabelian group is still open. Results for  , when a set has very small doubling, are referred to as Kneser theorems.[11]

The polynomial Freiman–Ruzsa conjecture,[12] is a generalization published in a paper[13] by Imre Ruzsa but credited by him to Katalin Marton. It states that if a subset of a group (a power of a cyclic group)   has doubling constant such that   then it is covered by a bounded number  of cosets of some subgroup   with . In 2012 Tom Sanders gave an almost polynomial bound of the conjecture for abelian groups.[14][15] In 2023 a solution over   a field of characteristic 2 has been posted as a preprint by Tim Gowers, Ben Green, Freddie Manners and Terry Tao.[16][17][18] This proof was completely formalized in the Lean 4 formal proof language, a collaborative project that marked an important milestone in terms of mathematicians successfully formalizing contemporary mathematics.[19]

See also

edit

References

edit
  1. ^ Freiman, G.A. (1964). "Addition of finite sets". Soviet Mathematics. Doklady. 5: 1366–1370. Zbl 0163.29501.
  2. ^ Freiman, G. A. (1966). Foundations of a Structural Theory of Set Addition (in Russian). Kazan: Kazan Gos. Ped. Inst. p. 140. Zbl 0203.35305.
  3. ^ Nathanson, Melvyn B. (1996). Additive Number Theory: Inverse Problems and Geometry of Sumsets. Graduate Texts in Mathematics. Vol. 165. Springer. ISBN 978-0-387-94655-9. Zbl 0859.11003. p. 252.
  4. ^ Ruzsa, I. Z. (August 1992). "Arithmetical progressions and the number of sums". Periodica Mathematica Hungarica. 25 (1): 105–111. doi:10.1007/BF02454387. ISSN 0031-5303.
  5. ^ Ruzsa, Imre Z. (1994). "Generalized arithmetical progressions and sumsets". Acta Mathematica Hungarica. 65 (4): 379–388. doi:10.1007/bf01876039. Zbl 0816.11008.
  6. ^ Chang, Mei-Chu (2002). "A polynomial bound in Freiman's theorem". Duke Mathematical Journal. 113 (3): 399–419. CiteSeerX 10.1.1.207.3090. doi:10.1215/s0012-7094-02-11331-3. MR 1909605.
  7. ^ Sanders, Tom (2013). "The structure theory of set addition revisited". Bulletin of the American Mathematical Society. 50: 93–127. arXiv:1212.0458. doi:10.1090/S0273-0979-2012-01392-7. S2CID 42609470.
  8. ^ Zhao, Yufei. "Graph Theory and Additive Combinatorics" (PDF). Archived from the original (PDF) on 2019-11-23. Retrieved 2019-12-02.
  9. ^ Ruzsa, Imre Z.; Green, Ben (2007). "Freiman's theorem in an arbitrary abelian group". Journal of the London Mathematical Society. 75 (1): 163–175. arXiv:math/0505198. doi:10.1112/jlms/jdl021. S2CID 15115236.
  10. ^ Tao, Terence (2010). "Freiman's theorem for solvable groups". Contributions to Discrete Mathematics. 5 (2): 137–184. doi:10.11575/cdm.v5i2.62020.
  11. ^ Tao, Terence (10 November 2009). "An elementary non-commutative Freiman theorem". Terence Tao's blog.
  12. ^ "(Ben Green) The Polynomial Freiman–Ruzsa conjecture". What's new. 2007-03-11. Retrieved 2023-11-14.
  13. ^ Ruzsa, I. (1999). "An analog of Freiman's theorem in groups" (PDF). Astérisque. 258: 323–326.
  14. ^ Sanders, Tom (2012-10-15). "On the Bogolyubov–Ruzsa lemma". Analysis & PDE. 5 (3): 627–655. arXiv:1011.0107. doi:10.2140/apde.2012.5.627. ISSN 1948-206X.
  15. ^ Brubaker, Ben (2023-12-04). "An Easy-Sounding Problem Yields Numbers Too Big for Our Universe". Quanta Magazine. Retrieved 2023-12-11.
  16. ^ Gowers, W. T.; Green, Ben; Manners, Freddie; Tao, Terence (2023). "On a conjecture of Marton". arXiv:2311.05762 [math.NT].
  17. ^ "On a conjecture of Marton". What's new. 2023-11-13. Retrieved 2023-11-14.
  18. ^ Sloman, Leila (December 6, 2023). "'A-Team' of Math Proves a Critical Link Between Addition and Sets". Quanta Magazine. Retrieved December 16, 2023.
  19. ^ "The Polynomial Freiman-Ruzsa Conjecture". PFR Project homepage.

Further reading

edit


This article incorporates material from Freiman's theorem on PlanetMath, which is licensed under the Creative Commons Attribution/Share-Alike License.