\documentclass[12pt ]{article} \setlength{\textwidth}{14 true cm} \setlength{\textheight}{20 true cm} \usepackage{hangul} \usepackage{amscd,amsmath} \usepackage{amsfonts} \usepackage{amssymb,theorem} \usepackage{longtable} \usepackage{floatflt} \usepackage{texdraw, epic, pstcol ,pstricks ,pst-3d, pst-poly,pst-grad,pst-node, pst-text} \usepackage{floatflt} \usepackage[arrow,matrix]{xy} \usepackage{graphicx} \newcommand{\Aff}{\mbox{\it Aff}} \newcommand{\aff}{\mbox{\it aff}} \newcommand{\alp}{\alpha} \newcommand{\bet}{\beta} \newcommand{\del}{\delta} \newcommand{\gam}{\gamma} \newcommand{\vep}{\varepsilon} \newcommand{\eps}{\epsilon} \newcommand{\lam}{\lambda} \newcommand{\kap}{\kappa} \newcommand{\sig}{\sigma} \newcommand{\ome}{\omega} \newcommand{\Gam}{\Gamma} \newcommand{\Ome}{\Omega} \newcommand{\Sig}{\Sigma} \newcommand{\Del}{\Delta} \newcommand{\Lam}{\Lambda} \newcommand{\disi}{\displaystyle{\sum_{i=1}^n}} \newcommand{\disj}{\displaystyle{\sum_{j=1}^m}} \newcommand{\rb}{\mathbb{R}} \newcommand{\zb}{\mathbb{Z}} \newcommand{\bd}{\partial} \newcommand{\key}[1]{\emph{\textbf{#1}}} \newcommand{\rh}[1]{\widetilde{H}(#1)} \newcommand{\hh}{\widetilde{H_*}} \newcommand{\h}{\widetilde{H}} \newcommand{\hhp}{\widetilde{H}_p} \newcommand{\ssx}[1][p]{\triangle^{#1}} \newcommand{\iosh}{i_{0\sharp}} \newcommand{\ish}{i_{1\sharp}} \newcommand{\ios}{i_{0*}} \newcommand{\is}{i_{1*}} \newcommand{\sm}{S^n-s^r} \newtheorem{thm}{Á¤¸®} \newtheorem{cor}[thm]{µû¸§Á¤¸®} \newtheorem{lem}[thm]{º¸Á¶Á¤¸®} \newtheorem{prop}[thm]{¸íÁ¦} \newtheorem{cl}{Claim} {\theorembodyfont{\rm} \newtheorem{ex}{¿¹} \newtheorem{que}{Áú¹®} \newtheorem{notation}{Notation}[section] \newtheorem{defn}{Á¤ÀÇ} \newtheorem{rem}{ÁÖ} \newtheorem{note}{Note} } \renewcommand{\thenote}{} \renewcommand{\therem}{} \newenvironment{pf}{{\bf Áõ¸í}}{\hfill\framebox[2mm]{}} \begin{document} \parindent=0cm \section*{VIII.2 Further Application to Sphere} \begin{defn} $f : S^n \rightarrow S^n \Rightarrow f_* : \hh (S^n ) \rightarrow \hh (S^n) $. \\Now let $\alp$ be a generator of $\hh(S^n ) \cong \mathbb{Z}$ and let $f_* (\alp) = d \alp.$\\ Then the integer $d$ is independent of choice of a generator $\alp$, and is called the degree of $f$. \end{defn} \textbf{Remark.} $M^n$ : connected orientable closed $n$-manifold $\Rightarrow$ degree is defined. \begin{thm} (Basic properties of degree)\\ (i) $f \simeq g \Rightarrow $ deg $f$ = deg $g$\\ (ii) deg ($f\circ g) \Rightarrow $(deg $f)$(deg $g$)\\ (iii) deg (id) = 1\\ (iv) deg ($c$) = 0 , where $c$ is a constant map.\end{thm} \begin{pf} (i) $\sim$ (iii) : clear\\ (iv) $c$ : constant map $\Rightarrow c_* = 0 : \widetilde{H} (X) \rightarrow \widetilde{H} (X)$\\ ($c : X \overset{\bar{c}}{\rightarrow} x_0 \overset{i}{\hookrightarrow} X \Rightarrow c_* : \h (X) \overset{\bar{c_*}}{\rightarrow} \h (x_0 ) = 0 \overset{i_* }{\rightarrow}\h (X)$)\end{pf}\\ \textbf{Note.} (1) $\alp_n : S^1 \rightarrow S^1 \Rightarrow $ deg $(\alp_n ) = n$\\ $\hspace*{7em} z\rightarrow z^n$\\ \begin{pf} \[ \xymatrix @M=1ex @C=3em @R=1em @*[c]{% \pi_1(S^1) \ar[rr]^{(\alp_n )_\sharp} \ar[dd]^{\chi : \cong}& & \pi_1 (S^1 ) \ar[dd]^{\chi : \cong} \\ &\curvearrowright & \\ H_1 (S^1 ) \ar[rr]^{(\alp_n )_*} & & H_1 (S^1 )} \] $\Rightarrow (\alp _n )_* \{\alp_1\} = \chi ((\alp_n)_\sharp [\alp_1] ) = \chi ([\alp_n \circ \alp_1 ]) = \chi ([\alp_n]) \\ \hspace*{5.5em}= \chi (n [\alp_1 ]) = n \chi [\alp_1 ] = n \{\alp_1\}$\end{pf}\\ (2) Brower fixed point theorem on $B^n$: Prove as follows.\\ (i) $S^n \overset{f}{\rightarrow} S^n \hspace{0.5em} \Rightarrow \hspace{0.5em}$deg$f = 0$ : Applying homology functor to the diagram \\ $\hspace*{1.5em} \cup \hspace{0.2em} \curvearrowright \hspace{0.2em} \nearrow \bar{f}\hspace{7em}$and note that $\widetilde{H}(B^n )=0$\\ $\hspace*{1em} B^{n+1}$\\ (ii) $\nexists$ retraction $r : B^{n+1} \rightarrow S^n : \\id : S^n \overset{i}{\rightarrow} B^{n+1} \overset{r}{\rightarrow} S^n \overset{(i)}{\Rightarrow}$deg$(id) = 0$, a contradiction.\\ (iii) $\forall \phi : B^n \rightarrow B^n$ has a fixed point : The proof is the same as before for the case of $B^2$. (If $\phi$ has no fixed point, we can construct a retraction:$B^n \rightarrow S^{n-1} .$) \begin{thm} Let $S^n \hookrightarrow \rb^{n+1}$ be the standard sphere and $f \in O(n+1,\rb )$ so that $f : S^n \rightarrow S^n . $ Then deg $f$ = det $f (= \pm$ 1) \end{thm} \begin{pf} \begin{lem} Let $r :S^n \rightarrow S^n$ be the reflection given by \\ $r(x_1 , x_2 , \cdots , x_{n+1} ) = (-x_1 , x_2 ,\cdots , x_{n+1}).$ Then deg $r$ = -1 = det $r$.\end{lem} \begin{pf} induction on $n$.\\ Let $S^0 = \{-1, 1\}$, and $x$ and $y$ be a 0-singular simplex which has image -1 and 1 respectively. $\widetilde{H_0}(S^0 ) = \{x-y\} $ and $r_* : x-y \mapsto y-x\\ \therefore$ deg $r = - 1$.\\ $n > 0 :$ MV sequence$ \Rightarrow$\\ \[ \xymatrix @M=1ex @C=3.5em @R=1em @*[c]{% \widetilde{H_n}(S^n ) \ar[rr]^{\bd_* : \cong} \ar[dd]^{r_*}& & \widetilde{H_{n-1}}(S^{n-1} )\ar[dd]^{r|_*}\\ & \circlearrowright & \\ \widetilde{H_n}(S^n ) \ar[rr]^{\bd_* : \cong}& & \widetilde{H_{n-1}}(S^{n-1} )} \] $\Rightarrow $ deg $r_* $ = deg $r|_*$\end{pf} \newpage \begin{lem} $f \in SO(n+1) \Rightarrow f \simeq id.$ \end{lem} \begin{pf} Essentially this is to show $SO(n+1)$ is path-connected.\\ Fact. $ A \in SO(n) \Rightarrow \exists B$ s.t. \begin{displaymath} BAB^{-1} = \left(\begin {array}{ccc} \left(\begin{array}{cc} cos \theta & -sin \theta\\ sin \theta & cos \theta \end{array}\right)& & \cdots \\ \vdots & \ddots & \\ & & 1 \end{array}\right)\overset{let}{=} D_{\theta} \end{displaymath} where $\theta=(\theta_1 , \cdots , \theta_i )$\footnote{ $< , >$ : standard inner product on $\mathbb{R}^n \rightsquigarrow$ ( , ) : standard Hermitian inner product on $\mathbb{C}^n \\ A \in O(n) \Rightarrow A$ is an isometry for ( , )\\ Let $Ax = \lambda x \Rightarrow \lambda\bar{\lambda}(x,x) = (Ax , Ax) = (x,x) \Rightarrow |\lambda | =1 \\ A:$ real $\Rightarrow e^{i\theta}, e^{-i\theta} :$ conjugate eigenvlaues in general $\Rightarrow Az = (cos\theta + i sin \theta )z \Rightarrow x =\frac{z + \bar{z}}{2} \\ \hspace*{24.5em} A\bar{z} = (cos \theta - i sin \theta)\bar{z}\hspace{1.5em} y =\frac{z - \bar{z}}{2} i $\\ Then $A$ can be written as $\left(\begin{array}{cc} cos \theta & -sin \theta\\ sin \theta & cos \theta \end{array}\right)$ \\with repect to a basis $\{x,y\}$ where $x =\frac{z + \bar{z}}{2}$ and $y =\frac{z - \bar{z}}{2} i$. } Using fact, $H_t = B^{-1}D_{t{\theta}} B : I \simeq A\hspace{1em} (t = 0 $ ÀÏ ¶§ $I, t = 1$ ÀÏ ¶§ $A$)\end{pf}\\ Á¤¸® 2 Áõ¸í °è¼Ó\\ Now note that $O(n+1) = SO(n+1) \cup rSO(n+1) \overset{det}{\rightarrow} \{ -1, 1\} = \mathbb{Z} / 2$.(º¸Á¶Á¤¸® 3, 4·ÎºÎÅÍ) $\therefore $ deg = det \end{pf} \begin{cor} $a : S^n \rightarrow S^n$ the antipodal map $\Rightarrow $ deg $a = (-1)^{n+1}$.\end{cor} \begin{thm} $f, g : S^n \rightarrow S^n $ with $f(x) \neq g(x)\hspace{1em} \forall x\in S^n \Rightarrow f \simeq ag$.\\ (or equivalently, $f$ and $g$ are never antipodal $\Rightarrow f\simeq g$)\end{thm} \begin{pf} $f(x) \neq g(x) \hspace{1em} \forall x \Rightarrow f(x)$ and $ag(x)$ are not antipodal. \\ $\Rightarrow (1-t)f(x) + tag(x) \neq 0$\\ $F : S^n \times I \Rightarrow S^n $ given by $ F(x,t) = \frac{(1-t)f(x) + tag(x)}{| (1-t)f(x) + tag(x) |}$ is the desired homotopy.\end{pf} \begin{cor} (1) $f$ has no fixed point. $\Rightarrow f \simeq a$\\ (2) deg $f \neq (-1)^{n+1} \Rightarrow f$ has a fixed point.\end{cor} \begin{pf} (1) $f(x) \neq id(x) \overset{Á¤¸® 6}{\Rightarrow} f\simeq a$ \end{pf}\\ exc. Is the converse of (1) true?\\ \textbf{¼÷Á¦ 1.} ¹®Á¦ 16.11. \begin{thm} $S^n$ has a non-vanishing vector field iff $n=$ odd.\end{thm} \begin{pf} $(\Leftarrow ) n = 2m +1 \Rightarrow $ let $ v(x_0 ,\cdots , x_{2m+1} ) = (-x_1 , x_0 , -x_3 , x_2 , \cdots , -x_{2m+1} , x_{2m } )$\\ $(\Rightarrow) $ Suppose $\exists$ a non-vanishing vector field $v,$ we may assume $|v(x)| = 1 \\ \Rightarrow F(x,t) = (cos\hspace{0.2em} t\pi )x + (sin\hspace{0.2em} t\pi )v(x)$ gives a homotopy : $id \simeq a \\ \Rightarrow $ deg $(id)$ = deg $(a) = (-1)^{n+1} \\ \Rightarrow n = $ odd.\end{pf}\\ \textbf{Remark.} vector field problem for $S^{odd}$: \\Adams solution : Let $n+1 = (odd) 2^{4a+b},\hspace{1em} 0\leqslant b\leqslant 3$. Then the number of independent vector fields on $S^n$ = $ 2^b + 8a -1.$\\ \textbf{¼÷Á¦ 2. } ¹®Á¦ 16.10. \end{document}