Non-symmetric polarization
Abstract
Let be an -homogeneous polynomial in -complex variables . Clearly, has a unique representation in the form \begin{equation*} P(x)= \sum_{1 \leq j_1 \leq \dotsc \leq j_m \leq n} c_{(j_1, \dotsc, j_m)} \, x_{j_1} \dotsb x_{j_m} \,, \end{equation*} and the "~form \begin{equation*} L_P(x^{(1)}, \dotsc, x^{(m)})= \sum_{1 \leq j_1 \leq \dotsc \leq j_m \leq n} c_{(j_1, \dotsc, j_m)} \, x^{(1)}_{j_1} \dotsb x^{(m)}_{j_m} \end{equation*} satisfies for every . We show that, although in general is non-symmetric, for a large class of reasonable norms on the norm of on up to a logarithmic term can be estimated by the norm of on ; here denotes a universal constant. Moreover, for the "~norms , the logarithmic term in the number of variables is even superfluous.
Cite
@article{arxiv.1603.04279,
title = {Non-symmetric polarization},
author = {Andreas Defant and Sunke Schlüters},
journal= {arXiv preprint arXiv:1603.04279},
year = {2016}
}