Probabilistic Schubert Calculus: asymptotics (1912.08291v1)
Abstract: In the paper [arXiv:1612.06893] P. B\"urgisser and A. Lerario introduced a geometric framework for a probabilistic study of real Schubert Problems. They denoted by $\delta_{k,n}$ the average number of projective $k$-planes in $\mathbb{R}\textrm{P}n$ that intersect $(k+1)(n-k)$ many random, independent and uniformly distributed linear projective subspaces of dimension $n-k-1$. They called $\delta_{k,n}$ the expected degree of the real Grassmannian $\mathbb{G}(k,n)$ and, in the case $k=1$, they proved that: $$ \delta_{1,n}= \frac{8}{3\pi{5/2}} \cdot \left(\frac{\pi2}{4}\right)n \cdot n{-1/2} \left( 1+\mathcal{O}\left(n{-1}\right)\right).$$ Here we generalize this result and prove that for every fixed integer $k>0$ and as $n\to \infty$, we have \begin{equation*} \delta_{k,n}=a_k \cdot \left(b_k\right)n\cdot n{-\frac{k(k+1)}{4}}\left(1+\mathcal{O}(n{-1})\right) \end{equation*} where $a_k$ and $b_k$ are some (explicit) constants, and $a_k$ involves an interesting integral over the space of polynomials that have all real roots. For instance: $$\delta_{2,n}= \frac{9\sqrt{3}}{2048\sqrt{2\pi}} \cdot 8n \cdot n{-3/2} \left( 1+\mathcal{O}\left(n{-1}\right)\right).$$ Moreover we prove that these numbers belong to the ring of periods intoduced by Kontsevich and Zagier and we give an explicit formula for $\delta_{1,n}$ involving a one dimensional integral of certain combination of Elliptic functions.
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