A bilinear Rubio de Francia inequality for arbitrary rectangles

Abstract: Let $\mathscr{R}$ be a collection of disjoint dyadic rectangles $R$ with sides parallel to the axes, let $\pi_R$ denote the non-smooth bilinear projection onto $R$ [ \pi_R (f,g)(x):=\iint \mathbf{1}{R}(\xi,\eta) \widehat{f}(\xi) \widehat{g}(\eta) e^{2\pi i (\xi + \eta) x} d\xi d\eta ] and let $r>2$. We show that the bilinear Rubio de Francia operator associated to $\mathscr{R}$ given by [ f,g \mapsto \Big(\sum{R\in\mathscr{R}} |\pi_{R} (f,g)|^r \Big)^{1/r} ] is $L^p \times L^q \rightarrow L^s$ bounded whenever $1/p + 1/q = 1/s$, $r'<p,q<r$. This extends from squares to rectangles a previous result by the same authors, and as a corollary extends in the same way a previous result from Benea and the first author for smooth projections, albeit in a reduced range.