Markov–Kakutani fixed-point theorem

In mathematics, the Markov–Kakutani fixed-point theorem, named after Andrey Markov and Shizuo Kakutani, states that a commuting family of continuous affine self-mappings of a compact convex subset in a locally convex topological vector space has a common fixed point. This theorem is a key tool in one of the quickest proofs of amenability of abelian groups.

Statement

Let X {\displaystyle X} be a locally convex topological vector space, with a compact convex subset K {\displaystyle K} . Let S {\displaystyle S} be a family of continuous mappings of K {\displaystyle K} to itself which commute and are affine, meaning that T ( λ x + ( 1 λ ) y ) = λ T ( x ) + ( 1 λ ) T ( y ) {\displaystyle T(\lambda x+(1-\lambda )y)=\lambda T(x)+(1-\lambda )T(y)} for all λ {\displaystyle \lambda } in ( 0 , 1 ) {\displaystyle (0,1)} and T {\displaystyle T} in S {\displaystyle S} . Then the mappings in S {\displaystyle S} share a fixed point.[1]

Proof for a single affine self-mapping

Let T {\displaystyle T} be a continuous affine self-mapping of K {\displaystyle K} .

For x {\displaystyle x} in K {\displaystyle K} define a net { x ( N ) } N N {\displaystyle \{x(N)\}_{N\in \mathbb {N} }} in K {\displaystyle K} by

x ( N ) = 1 N + 1 n = 0 N T n ( x ) . {\displaystyle x(N)={1 \over N+1}\sum _{n=0}^{N}T^{n}(x).}

Since K {\displaystyle K} is compact, there is a convergent subnet in K {\displaystyle K} :

x ( N i ) y . {\displaystyle x(N_{i})\rightarrow y.\,}

To prove that y {\displaystyle y} is a fixed point, it suffices to show that f ( T y ) = f ( y ) {\displaystyle f(Ty)=f(y)} for every f {\displaystyle f} in the dual of X {\displaystyle X} . (The dual separates points by the Hahn-Banach theorem; this is where the assumption of local convexity is used.)

Since K {\displaystyle K} is compact, | f | {\displaystyle |f|} is bounded on K {\displaystyle K} by a positive constant M {\displaystyle M} . On the other hand

| f ( T x ( N ) ) f ( x ( N ) ) | = 1 N + 1 | f ( T N + 1 x ) f ( x ) | 2 M N + 1 . {\displaystyle |f(Tx(N))-f(x(N))|={1 \over N+1}|f(T^{N+1}x)-f(x)|\leq {2M \over N+1}.}

Taking N = N i {\displaystyle N=N_{i}} and passing to the limit as i {\displaystyle i} goes to infinity, it follows that

f ( T y ) = f ( y ) . {\displaystyle f(Ty)=f(y).\,}

Hence

T y = y . {\displaystyle Ty=y.\,}

Proof of theorem

The set of fixed points of a single affine mapping T {\displaystyle T} is a non-empty compact convex set K T {\displaystyle K^{T}} by the result for a single mapping. The other mappings in the family S {\displaystyle S} commute with T {\displaystyle T} so leave K T {\displaystyle K^{T}} invariant. Applying the result for a single mapping successively, it follows that any finite subset of S {\displaystyle S} has a non-empty fixed point set given as the intersection of the compact convex sets K T {\displaystyle K^{T}} as T {\displaystyle T} ranges over the subset. From the compactness of K {\displaystyle K} it follows that the set

K S = { y K T y = y , T S } = T S K T {\displaystyle K^{S}=\{y\in K\mid Ty=y,\,T\in S\}=\bigcap _{T\in S}K^{T}\,}

is non-empty (and compact and convex).

Citations

  1. ^ Conway 1990, pp. 151–152.

References

  • Conway, John B. (1990). A Course in Functional Analysis. Graduate Texts in Mathematics. Vol. 96 (2nd ed.). New York: Springer-Verlag. ISBN 978-0-387-97245-9. OCLC 21195908.
  • Markov, A. (1936), "Quelques théorèmes sur les ensembles abéliens", Dokl. Akad. Nauk SSSR, 10: 311–314
  • Kakutani, S. (1938), "Two fixed point theorems concerning bicompact convex sets", Proc. Imp. Akad. Tokyo, 14: 242–245
  • Reed, M.; Simon, B. (1980), Functional Analysis, Methods of Mathematical Physics, vol. 1 (2nd revised ed.), Academic Press, p. 152, ISBN 0-12-585050-6