Kneser's theorem (combinatorics) explained

In the branch of mathematics known as additive combinatorics, Kneser's theorem can refer to one of several related theorems regarding the sizes of certain sumsets in abelian groups. These are named after Martin Kneser, who published them in 1953^[1] and 1956.^[2] They may be regarded as extensions of the Cauchy–Davenport theorem, which also concerns sumsets in groups but is restricted to groups whose order is a prime number.

The first three statements deal with sumsets whose size (in various senses) is strictly smaller than the sum of the size of the summands. The last statement deals with the case of equality for Haar measure in connected compact abelian groups.

Strict inequality

is an abelian group and

is a subset of

, the group

H(C):=\{g\inG:g+C=C\}

is the stabilizer of

Cardinality

Let

be an abelian group. If

and

are nonempty finite subsets of

satisfying

|A+B|<|A|+|B|

and

is the stabilizer of

A+B

, then

\begin{align}|A+B|&=|A+H|+|B+H|-|H|.\end{align}

This statement is a corollary of the statement for LCA groups below, obtained by specializing to the case where the ambient group is discrete. A self-contained proof is provided in Nathanson's textbook.^[3]

Lower asymptotic density in the natural numbers

The main result of Kneser's 1953 article^[1] is a variant of Mann's theorem on Schnirelmann density.

is a subset of

, the lower asymptotic density of

is the number

\underline{d}(C):=\liminf_n\toinfty

	\|C\cap\{1,...,n\
	\|}{n}

. Kneser's theorem for lower asymptotic density states that if

and

are subsets of

satisfying

\underline{d}(A+B)<\underline{d}(A)+\underline{d}(B)

, then there is a natural number

such that

H:=kN\cup\{0\}

satisfies the following two conditions:

(A+B+H)\setminus(A+B)

is finite,

and

\underline{d}(A+B)=\underline{d}(A+H)+\underline{d}(B+H)-\underline{d}(H).

Note that

A+B\subseteqA+B+H

, since

0\inH

Haar measure in locally compact abelian (LCA) groups

Let

be an LCA group with Haar measure

and let

m_*

denote the inner measure induced by

(we also assume

is Hausdorff, as usual). We are forced to consider inner Haar measure, as the sumset of two

-measurable sets can fail to be

-measurable. Satz 1 of Kneser's 1956 article^[2] can be stated as follows:

and

are nonempty

-measurable subsets of

satisfying

m_*(A+B)<m(A)+m(B)

, then the stabilizer

H:=H(A+B)

is compact and open. Thus

A+B

is compact and open (and therefore

-measurable), being a union of finitely many cosets of

. Furthermore,

m(A+B)=m(A+H)+m(B+H)-m(H).

Equality in connected compact abelian groups

Because connected groups have no proper open subgroups, the preceding statement immediately implies that if

is connected, then

m_*(A+B)\geqmin\{m(A)+m(B),m(G)\}

for all

-measurable sets

and

. Examples where

can be found when

is the torus

T:=R/Z

and

are intervals. Satz 2 of Kneser's 1956 article^[2] says that all examples of sets satisfying equation with non-null summands are obvious modifications of these. To be precise: if

is a connected compact abelian group with Haar measure

and

are

-measurable subsets of

satisfying

m(A)>0,m(B)>0

, and equation, then there is a continuous surjective homomorphism

\phi:G\toT

and there are closed intervals

such that

A\subseteq\phi^-1(I)

B\subseteq\phi^-1(J)

m(A)=m(\phi^-1(I))

, and

m(B)=m(\phi^-1(J))

References

Book: Geroldinger . Alfred . Ruzsa . Imre Z. . Imre Z. Ruzsa . Elsholtz, C.; Freiman, G.; Hamidoune, Y. O.; Hegyvári, N.; Károlyi, G.; Nathanson, M.; Solymosi, J.; Stanchescu, Y. With a foreword by Javier Cilleruelo, Marc Noy and Oriol Serra (Coordinators of the DocCourse) . Combinatorial number theory and additive group theory . Advanced Courses in Mathematics CRM Barcelona . Basel . Birkhäuser . 2009 . 978-3-7643-8961-1 . 1177.11005.
Book: Grynkiewicz, David . Structural Additive Theory . 30. . . 2013 . 978-3-319-00415-0 . 1368.11109 . 61 . Grynk .

Notes and References

Martin . Kneser . Abschätzungen der asymptotischen Dichte von Summenmengen . German . . 58 . 1953 . 459–484 . 10.1007/BF01174162 . 0051.28104 . 120456416 .
Martin . Kneser . Summenmengen in lokalkompakten abelschen Gruppen . German . . 66 . 1956 . 88–110 . 10.1007/BF01186598 . 0073.01702 . 120125011 .
Book: Nathanson, Melvyn B. . Melvyn B. Nathanson . Additive Number Theory: Inverse Problems and the Geometry of Sumsets . 165 . . . 1996 . 0-387-94655-1 . 0859.11003 . 109–132 .