Difference between revisions of "User:Harold/Charting RP^n"
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This article contains information on possible {{link|chart||s}} for the real projective space of dimension <m>n</m>, denoted by <m>\RPn</m>. | This article contains information on possible {{link|chart||s}} for the real projective space of dimension <m>n</m>, denoted by <m>\RPn</m>. | ||
We shall first define <m>\RPn</m>. Let <m>S^n = \left\{ (x_0, \dotsc, x_n) \middle\vert \sum_{i = 0}^n x_i^2 = 1 \right\}</m> be the <m>n</m>-sphere. | We shall first define <m>\RPn</m>. Let <m>S^n = \left\{ (x_0, \dotsc, x_n) \middle\vert \sum_{i = 0}^n x_i^2 = 1 \right\}</m> be the <m>n</m>-sphere. | ||
| − | Define a group action <m>{-1, 1} \cong \Ztwo</> on <m>S^n</m> by mapping <m>(\epsilon, x) \mapsto \epsilon x</m> with <m>epsilon \in {-1, 1} | + | Define a group action <m>\{-1, 1\} \cong \Ztwo</m> on <m>S^n</m> by mapping <m>(\epsilon, x) \mapsto \epsilon x</m> with <m>\epsilon \in \{-1, 1\}</m> and <m>x \in S^n</m>. |
| − | This group action is "nice enough" so that the quotient space <m>S^n / \Ztwo</m> is actually a real smooth compact Hausdorff manifold. | + | This group action is "nice enough" so that the quotient space <m>S^n / \left( \Ztwo \right) </m> is actually a real smooth compact Hausdorff manifold. |
| + | |||
| + | We now construct (the) (smooth) charts on {{M|\RPn}}. | ||
| + | First we introduce some notation: if {{M|x \in \RPn}}, we write {{M|1=x = [x_0 : \dotsc : x_n]}} if {{M|(x_0, \dotsc, x_n)}} is a representative of the equivalence class {{M|x}}. | ||
| + | Define the subsets {{M|U_i \subset \RPn}} for {{M|0 \leq i \leq n}} as | ||
| + | {{MM|1=U_i := \{ [x_0 : \dotsc : x_n] \in \RPn \vert x_i \neq 0 \}. }} | ||
| + | This is well-defined, because the choice of representative only depends on a sign or a non-zero scalar multiple (if the definition of lines in {{M|\R^n}} is chosen; see {{link|Real projective space}}). | ||
| + | Now introduce maps | ||
| + | |||
| + | <mm> | ||
| + | \begin{align*} | ||
| + | \phi_i: U_i & \to \R^n \\ | ||
| + | [x_0 : \dotsc : x_{i - 1} : 1 : x_{i+1} : \dotsc : x_n] & \mapsto (x_0, \dotsc, \widehat{x_i}, \dotsc, x_n) | ||
| + | \end{align*} | ||
| + | </mm> | ||
| + | |||
| + | where {{M| \widehat{x_i} }} denotes that the {{M|i}}-th coordinate is omitted. | ||
| + | These maps are well-defined, and homeomorphisms if one takes the quotient topology on {{M|\RPn}}, and actually define a smooth structure on {{M|\RPn}}, as the transition maps {{M| \phi_j \circ \phi_i^{-1} }} are diffeomorphisms (where defined). | ||
Revision as of 14:38, 19 February 2017
\newcommand{\R}{\mathbb{R}} \newcommand{\RPn}{\R P^n} \newcommand{\Ztwo}{\mathbb{Z} / 2 \mathbb{Z}} This article contains information on possible charts for the real projective space of dimension n, denoted by \RPn. We shall first define \RPn. Let S^n = \left\{ (x_0, \dotsc, x_n) \middle\vert \sum_{i = 0}^n x_i^2 = 1 \right\} be the n-sphere. Define a group action \{-1, 1\} \cong \Ztwo on S^n by mapping (\epsilon, x) \mapsto \epsilon x with \epsilon \in \{-1, 1\} and x \in S^n. This group action is "nice enough" so that the quotient space S^n / \left( \Ztwo \right) is actually a real smooth compact Hausdorff manifold.
We now construct (the) (smooth) charts on \RPn. First we introduce some notation: if x \in \RPn, we write x = [x_0 : \dotsc : x_n] if (x_0, \dotsc, x_n) is a representative of the equivalence class x. Define the subsets U_i \subset \RPn for 0 \leq i \leq n as U_i := \{ [x_0 : \dotsc : x_n] \in \RPn \vert x_i \neq 0 \}. This is well-defined, because the choice of representative only depends on a sign or a non-zero scalar multiple (if the definition of lines in \R^n is chosen; see Real projective space). Now introduce maps
\begin{align*} \phi_i: U_i & \to \R^n \\ [x_0 : \dotsc : x_{i - 1} : 1 : x_{i+1} : \dotsc : x_n] & \mapsto (x_0, \dotsc, \widehat{x_i}, \dotsc, x_n) \end{align*}
where \widehat{x_i} denotes that the i-th coordinate is omitted. These maps are well-defined, and homeomorphisms if one takes the quotient topology on \RPn, and actually define a smooth structure on \RPn, as the transition maps \phi_j \circ \phi_i^{-1} are diffeomorphisms (where defined).
