Ergodic Theorems for Nonconventional Arrays and an Extension of the Szemeredi Theorem

Abstract

The paper is primarily concerned with the asymptotic behavior as N∞ of averages of nonconventional arrays having the form N-1Σn=1NΠj=1 TPj(n,N)fj where fj's are bounded measurable functions, T is an invertible measure preserving transformation and Pj's are polynomials of n and N taking on integer values on integers. It turns out that when T is weakly mixing and Pj(n,N)=pjn+qjN are linear or, more generally, have the form Pj(n,N)=Pj(n)+Qj(N) for some integer valued polynomials Pj and Qj then the above averages converge in L2 but for general polynomials Pj the L2 convergence can be ensured even in the case =1 only when T is strongly mixing. Studying also weakly mixing and compact extensions and relying on Furstenberg's structure theorem we derive an extension of Szemer\' edi's theorem saying that for any subset of integers with positive upper density there exists a subset N of positive integers having uniformly bounded gaps such that for N∈ N and at least N,\,>0 of n's all numbers pjn+qjN,\, j=1,..., belong to . We obtain also a version of these results for several commuting transformations which yields a corresponding extension of the multidimensional Szemer\' edi theorem.