A modified Christoffel function and its asymptotic properties
Abstract: We introduce a certain variant (or regularization) $\tilde{\Lambda}\mu_n$ of the standard Christoffel function $\Lambda\mu_n$ associated with a measure $\mu$ on a compact set $\Omega\subset \mathbb{R}d$. Its reciprocal is now a sum-of-squares polynomial in the variables $(x,\varepsilon)$, $\varepsilon>0$. It shares the same dichotomy property of the standard Christoffel function, that is, the growth with $n$ of its inverse is at most polynomial inside and exponential outside the support of the measure. Its distinguishing and crucial feature states that for fixed $\varepsilon>0$, and under weak assumptions, $\lim_{n\to\infty} \varepsilon{-d}\tilde{\Lambda}\mu_n(\xi,\varepsilon)=f(\zeta_\varepsilon)$ where $f$ (assumed to be continuous) is the unknown density of $\mu$ w.r.t. Lebesgue measure on $\Omega$, and $\zeta_\varepsilon\in\mathbf{B}\infty(\xi,\varepsilon)$ (and so $f(\zeta\varepsilon)\approx f(\xi)$ when $\varepsilon>0$ is small). This is in contrast with the standard Christoffel function where if $\lim_{n\to\infty} nd\Lambda\mu_n(\xi)$ exists, it is of the form $f(\xi)/\omega_E(\xi)$ where $\omega_E$ is the density of the equilibrium measure of $\Omega$, usually unknown. At last but not least, the additional computational burden (when compared to computing $\Lambda\mu_n$) is just integrating symbolically the monomial basis $(x{\alpha})_{\alpha\in\mathbb{N}d_n}$ on the box ${x: \Vert x-\xi\Vert_\infty<\varepsilon/2}$, so that $1/\tilde{\Lambda}\mu_n$ is obtained as an explicit polynomial of $(\xi,\varepsilon)$.
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