A symmetric multivariate Elekes-R\'onyai theorem

Abstract

We consider a polynomial P∈ R[x1,·s, xd] of degree δ that depends non-trivially on each of x1,...,xd with d≥ 2. For any integer t with 2≤ t≤ d, any natural number n ∈ N, and any finite set A ⊂ R of size n, our first result shows that \[ |P(A, A, …, A)| δ n32 - 12d-t+2, \] unless align* &P(x1, x2, …, xd) = f( u1(x1) + u2(x2) + ·s + ud(xd) ) or &P(x1, x2, …, xd) = f( v1(x1) v2(x2) ·s vd(xd) ), align* where f, ui, and vi are nonconstant univariate polynomials over R, and there exists an index subset I ⊂eq [d] with |I| = t such that for any i, j ∈ I, we have ui = λij uj (in the additive case) or |vi|= |vj|ij (in the multiplicative case) for some constants λij∈ R≠ 0,ij∈Q+. This result generalizes the symmetric Elekes-R\'onyai theorem proved by Jing, Roy, and Tran. Our second result is a generalized Erdos-Szemer\'edi theorem for two polynomials in higher dimensions, generalizing another theorem by Jing, Roy, and Tran. A key ingredient in our proofs is a variation of a theorem by Elekes, Nathanson, and Ruzsa.

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