تقرير
Homotopy type of spaces of locally convex curves in the sphere S^3
| العنوان: | Homotopy type of spaces of locally convex curves in the sphere S^3 |
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| المؤلفون: | Alves, Emília, Goulart, Victor, Saldanha, Nicolau C. |
| سنة النشر: | 2022 |
| المجموعة: | Mathematics |
| مصطلحات موضوعية: | Mathematics - Geometric Topology, Mathematics - Algebraic Topology, 53C42, 34B05, 55P15, 57N20, 58B05 |
| الوصف: | Locally convex (or nondegenerate) curves in the sphere $S^n$ (or the projective space) have been studied for several reasons, including the study of linear ordinary differential equations of order $n+1$. Taking Frenet frames allows us to obtain corresponding curves $\Gamma$ in the group $Spin_{n+1}$; recall that $\Pi: Spin_{n+1} \to Flag_{n+1}$ is the universal cover of the space of flags. Let $L(z_0;z_1)$ be the space of such curves $\Gamma$ with prescribed endpoints $\Gamma(0) = z_0$, $\Gamma(1) = z_1$. The aim of this paper is to determine the homotopy type of the spaces $L_3(z_0;z_1)$ for all $z_0, z_1 \in Spin_4$. Recall that $Spin_4 = S^3 \times S^3 \subset H \times H$, where $H$ is the ring of quaternions. This paper relies heavily on previous publications. The earliest such paper solves the corresponding problem for curves in $S^2$. Another previous result (with B. Shapiro) reduces the problem to $z_0 = 1$ and $z_1 \in Quat_4$ where $Quat_4 \subset Spin_4$ is a finite group of order $16$ with center $Z(Quat_4) = \{(\pm 1,\pm 1)\}$. A more recent paper shows that for $z_1 \in Quat_4 \smallsetminus Z(Quat_4)$ we have a homotopy equivalence $L_3(1;z_1) \approx \Omega Spin_4$. In this paper we compute the homotopy type of $L_3(1;z_1)$ for $z_1 \in Z(Quat_4)$: it is equivalent to the infinite wedge of $\Omega Spin_4$ with an infinite countable family of spheres (as for the case $n = 2$). The structure of the proof is roughly the same as for the case $n = 2$ but some of the steps are much harder. In both cases we construct explicit subsets $Y \subset L_n(z_0;z_1)$ for which the inclusion $Y \subset \Omega Spin_{n+1}(z_0;z_1)$ is a homotopy equivalence. For $n = 3$, this is done by considering the itineraries of such curves. The itinerary of a curve in $L_n(1;z_1)$ is a finite word in the alphabet $S_{n+1} \smallsetminus \{e\}$ of nontrivial permutations. Comment: 34 pages, 4 figures |
| نوع الوثيقة: | Working Paper |
| URL الوصول: | http://arxiv.org/abs/2205.10928 |
| رقم الأكسشن: | edsarx.2205.10928 |
| قاعدة البيانات: | arXiv |
| الوصف غير متاح. |