概率舒伯特微积分:渐近性

Q3 Mathematics
Antonio Lerario, Léo Mathis
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引用次数: 3

摘要

在最近的论文Bürgisser和Lerario(Journal für die reine und angewantte Mathematik(Crelles J),2016)中,介绍了真实舒伯特问题概率研究的几何框架。它们用\(\delta_{k,n}\)表示\({\mathbb{R}}\mathrm{P}^n \)中与\((k+1)(n-k)\)许多维数为\(n-k-1)的随机、独立和均匀分布的线性投影子空间相交的投影k平面的平均数目。他们称\(\detal_{k,n}\)为实Grassmannian的期望度\({\mathbb{G}}(k,n)\),并且在情况\(k=1\)中,他们证明了:$$\ begin{aligned}\detat_{1,n}=\frac{8}{3\pi^{5/2}}}\cdot\left(\frac \right)。\end{aligned}$$在这里我们推广了这个结果,并证明了对于每个固定整数\(k>;0\)和\(n\rightarrow\infty\),我们有$$\ begin{align}\delta _{k,n}=a_k\cdot\left(b_k\right)^n\cdot n^{-\frac{k(k+1)}{4}}\left(1+{\mathcal{O}},并且\(a_k\)涉及在具有所有实根的多项式空间上的一个有趣的积分。例如:$$\begin{aligned}\delta _{2,n}=\frac{9\sqrt{3}}{2048\sqrt{2\pi}}}\cdot 8^n\cdot n^{-3/2}\left(1+{\mathcal{O}}\left(n ^{-1}\right)\right)。\end{aligned}$$此外,我们证明了这些数属于Kontsevich和Zagier引入的周期环,并给出了涉及某些椭圆函数组合的一维积分的\(δ_{1,n}\)的显式公式。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Probabilistic Schubert Calculus: Asymptotics

In the recent paper Bürgisser and Lerario (Journal für die reine und angewandte Mathematik (Crelles J), 2016) 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 \({\mathbb {R}}\mathrm {P}^n\) 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:

$$\begin{aligned} \delta _{1,n}= \frac{8}{3\pi ^{5/2}} \cdot \left( \frac{\pi ^2}{4}\right) ^n \cdot n^{-1/2} \left( 1+{\mathcal {O}}\left( n^{-1}\right) \right) . \end{aligned}$$

Here we generalize this result and prove that for every fixed integer \(k>0\) and as \(n\rightarrow \infty \), we have

$$\begin{aligned} \delta _{k,n}=a_k \cdot \left( b_k\right) ^n\cdot n^{-\frac{k(k+1)}{4}}\left( 1+{\mathcal {O}}(n^{-1})\right) \end{aligned}$$

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:

$$\begin{aligned} \delta _{2,n}= \frac{9\sqrt{3}}{2048\sqrt{2\pi }} \cdot 8^n \cdot n^{-3/2} \left( 1+{\mathcal {O}}\left( n^{-1}\right) \right) . \end{aligned}$$

Moreover we prove that these numbers belong to the ring of periods intoduced by Kontsevich and Zagier and give an explicit formula for \(\delta _{1,n}\) involving a one-dimensional integral of certain combination of Elliptic functions.

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来源期刊
Arnold Mathematical Journal
Arnold Mathematical Journal Mathematics-Mathematics (all)
CiteScore
1.50
自引率
0.00%
发文量
28
期刊介绍: The Arnold Mathematical Journal publishes interesting and understandable results in all areas of mathematics. The name of the journal is not only a dedication to the memory of Vladimir Arnold (1937 – 2010), one of the most influential mathematicians of the 20th century, but also a declaration that the journal should serve to maintain and promote the scientific style characteristic for Arnold''s best mathematical works. Features of AMJ publications include: Popularity. The journal articles should be accessible to a very wide community of mathematicians. Not only formal definitions necessary for the understanding must be provided but also informal motivations even if the latter are well-known to the experts in the field. Interdisciplinary and multidisciplinary mathematics. AMJ publishes research expositions that connect different mathematical subjects. Connections that are useful in both ways are of particular importance. Multidisciplinary research (even if the disciplines all belong to pure mathematics) is generally hard to evaluate, for this reason, this kind of research is often under-represented in specialized mathematical journals. AMJ will try to compensate for this.Problems, objectives, work in progress. Most scholarly publications present results of a research project in their “final'' form, in which all posed questions are answered. Some open questions and conjectures may be even mentioned, but the very process of mathematical discovery remains hidden. Following Arnold, publications in AMJ will try to unhide this process and made it public by encouraging the authors to include informal discussion of their motivation, possibly unsuccessful lines of attack, experimental data and close by research directions. AMJ publishes well-motivated research problems on a regular basis.  Problems do not need to be original; an old problem with a new and exciting motivation is worth re-stating. Following Arnold''s principle, a general formulation is less desirable than the simplest partial case that is still unknown.Being interesting. The most important requirement is that the article be interesting. It does not have to be limited by original research contributions of the author; however, the author''s responsibility is to carefully acknowledge the authorship of all results. Neither does the article need to consist entirely of formal and rigorous arguments. It can contain parts, in which an informal author''s understanding of the overall picture is presented; however, these parts must be clearly indicated.
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