A refinement of Cauchy-Schwarz complexity

Abstract

We introduce a notion of complexity for systems of linear forms, called sequential Cauchy-Schwarz complexity, which is parametrized by two positive integers k, and refines the notion of Cauchy-Schwarz complexity introduced by Green and Tao. We prove that if a system of linear forms has sequential Cauchy-Schwarz complexity at most (k,) then any average of 1-bounded functions over this system is controlled by the 21--th power of the Gowers Uk+1-norms of the functions. For =1 this agrees with Cauchy-Schwarz complexity, but for >1 there are systems that have sequential Cauchy-Schwarz complexity at most (k,) whereas their Cauchy-Schwarz complexity is greater than k. Our main application illustrates this with systems over a prime field Fp that are denoted by k,M and can be viewed as M-dimensional arithmetic progressions of length k. For each M≥ 2 we prove that k,M has sequential Cauchy-Schwarz complexity at most (k-2,|k,M|) (where |k,M| is the number of forms in the system), whereas the Cauchy-Schwarz complexity of k,M can be greater than k-2. Thus we obtain polynomial true-complexity bounds for k,M with exponent 2-|k,M|. A recent general theorem of Manners, proved independently with different methods, implies a similar application but with different polynomial true-complexity bounds, as explained in the paper. In separate work, we use our application to give a new proof of the inverse theorem for Gowers norms on Fpn, and related results concerning ergodic actions of Fpω.