用户: Eee/Problem set on Geometry and Topology

Contents

1留言
2Milnor and Stasheff
3Poincaré Hopf theorem
4Topology

1留言

2Milnor and Stasheff

Problem 1-C

For any smooth manifold $M$ show that the collection $F = C^{\infty} (M, R)$ of smooth real valued functions on $M$ can be made into a ring, and that every point $x \in M$ determines a ring homomorphism $r_{x} : F \to R$ and hence a maximal ideal in $F$ .

If $M$ is compact, show that every maximal ideal in $F$ arises this way from a point in $M$ .

More generally, if there is a countable basis for the topology of $M$ , show that every ring homomorphism $F \to R$ is obtained in this way. Thus the smooth manifold $M$ is completely determined by the ring $F$ .

Solution.

First, the collection $F = C^{\infty} (M, R)$ is naturally a ring with the regular addition and multiplication. Now we consider the ring homomorphism $r_{x} : F \to R$ more specifically. For any $f \in F$ , we set $r_{x} (f) = f (x) \in R$ and then $r_{x}$ becomes a ring homomorphism naturally. Then we need to show $ker r_{x}$ is a maximal ideal of ring $F$ .

We remark that $ker r_{x} = {f \in F ∣ f (x) = 0}$ , and for any $g \in F$ , we have $g \cdot ker r_{x} \subset ker r_{x}$ , which shows $ker r_{x}$ is an ideal. For the maximality, for any $g \in F \ ker r_{x}$ , we show that $Sp a n_{F} ({g} \cup ker r_{x}) = F$ .

Since $g \neq = ker r_{x}$ , we see $c = g (x) \neq = 0$ . Consider the constant map $c (y) = c$ , $\forall y \in M$ , then $(g - c) (x) = g (x) - c (x) = c - c = 0$ which implies $g - c \in ker r_{x}$ . Then $c \in Sp a n_{F} ({g} \cup ker r_{x})$ . Specially, the multiplicative identity $1 = \frac{1}{c} c \in Sp a n_{F} ({g} \cup ker r_{x})$ , then we see $Sp a n_{F} ({g} \cup ker r_{x}) = F$ . (Actually, we just used a algebraic property: the kernel of a ring homomorphism is a maximal ideal, if the image ring is a field.)

Then we move on to the second question, let $I$ be any maximal ideal in $F$ . First we state that there is a point $x_{0} \in M$ such that $f (x_{0}) = 0$ for any $f \in I$ . Otherwise, for any point $x \in M$ , there exists a function $f_{x} \in I$ s.t. $f_{x} (0) \neq = 0$ . By the smoothness of $f$ , there exists a neighborhood $U_{x}$ of $x$ such that $f$ is nowhere $0$ in $U_{x}$ . Then we get an open covering ${U_{x}}_{x \in M}$ of $M$ , by the compactness of $M$ , it has a sub-covering ${U_{x_{i}}}_{i = 1}^{n}$ of $M$ . Hence we have ${f_{x_{i}}}$ satisfying $f_{x_{i}}$ is nowhere $0$ in $U_{x_{i}}$ . We set $f = f_{x_{1}}^{2} + \dots + f_{x_{n}}^{2}$ , then $f \in I$ and $f > 0$ in the entire $M$ . Then $\frac{1}{f} \in F$ exists, and the multiplicative identity $1 = \frac{1}{f} \cdot f \in I$ , then $I = F$ , a contradiction! Thus there is a point $x_{0} \in M$ such that $f (x_{0}) = 0$ for any $f \in I$ , from the last question, we have a maximal ideal $ker r_{x_{0}}$ and apparently $I \subset ker r_{x_{0}}$ . By the maximality of these two ideals, they are identical.

The ring homomorphism $F \to R$ defines a maximal ideal, the kernel ring. Actually, the compactness of $M$ is not necessary. For a second countable space, i.e. there is a countable topology basis, any open covering has a countable sub-covering. Back to the last paragraph, the open covering ${U_{x}}_{x \in M}$ (additionally, we choose $U_{x}$ small enough s.t. $\overline{U_{x}}$ is compact) has a countable sub-covering ${U_{i}}_{i = 1}^{\infty}$ . Then we have a function set ${f_{i}}_{i = 1}^{\infty}$ satisfying $f_{i}$ is nowhere $0$ in $U_{i}$ .

Since $\overline{U_{i}}$ is compact, we consider a greater open set $V_{i} \supset \overline{U_{i}}$ satisfying $\overline{V_{i}}$ is still compact. Then $∣ f_{i} ∣$ is bounded in $V_{i}$ due to the compactness of $V_{i}$ . Consider a special smooth function $g_{i}$ s.t. $g_{i} ∣_{U_{i}} \equiv 1$ and $g_{i} ∣_{M \ V_{i}} \equiv 0$ . Then we define $\tilde{f}_{i} = c_{i} \cdot g_{i} \cdot f_{i}$ , where $c_{i}$ is a constant small enough s.t. $∣ \tilde{f}_{i} ∣ \leq 1$ . Thus, we could define the desired function $\tilde{f} = n = 1 \sum \infty \frac{1}{n ^{2}} \tilde{f}_{n}^{2}$ . We could verify that $\tilde{f}$ is convergent and positive at every point of $M$ . Similar to the last question, we could show that this maximal ideal arises from a point of $M$ and the point is unique.

Thus, every ring homomorphism defines a maximal ideal, which is proved to be identical to a maximal ideal defined by a unique point.

Problem 3-E

Show that the set of isomorphism classes of $1$ -dimensional vector bundles over $B$ forms an abelian group with respect to the tensor product operation. Show that a given $R$ -bundle $ξ$ possesses a Euclidean metric if and only if $ξ$ represents an element of order $\leq 2$ in this group.

Proof.

The last problem is interesting. We assert that if the bundle $ξ$ is orientable and possesses a Euclidean metric, then $ξ$ is trivial.

If $ξ$ possesses a Euclidean metric $g ： E \to R$ , then $g$ assigns every fiber $E_{b}$ two vectors $v_{b}^{1}$ and $v_{b}^{2}$ satisfying $g (v_{b}^{i}) = 1$ , where $b \in B$ .

If $ξ$ is orientable, then we could choose a vector $v_{b}^{i}$ on every $b$ , which then becomes a global section $v (b)$ . The continuity of $v$ is given by the continuity of $g$ . Since $ξ$ has a non-where zero global section $v$ , then $ξ$ is trivial.

Note that $ξ \otimes ξ$ is always orientable, and we could endow a Euclidean metric induced by $ξ$ , thus $ξ \otimes ξ$ is trivial.

Problem 3-F

Let $B$ be a Tychonoff space and let $R (B)$ denote the ring of continuous real valued functions on $B$ . For any vector bundle $ξ$ over $B$ , let $S (ξ)$ denote the $R$ -module consisting of all cross-sections of $ξ$ .

1.	Show that $S (ξ \oplus η) ≅ S (ξ) \oplus S (η)$ .(This is trivial.) Show that $ξ$ is trivial if and only if $S (η)$ is free. (If $S (η)$ is free, then it possesses a basis which consisits of $n$ non-where dependent cross-sections making $ξ$ trivial.)
2.	If $ξ \oplus η$ is trivial, show that $S (ξ)$ is a finitely generated projective module. Conversely if $Q$ is a finitely generated projective module over $R (B)$ , show that $Q ≅ S (ξ)$ for some $ξ$ .
Proof	Since $S (ξ) \oplus S (η) = S (ξ \oplus η)$ which is a free module, then $S (ξ)$ is projective. If $Q$ is a finitely generated projective module, then there exists another module $P$ such that $Q \oplus P = R (B)^{n}$ . Then we construct a trivial bundle $B \times R (B)^{n}$ on $B$ . Let ${e_{1}, \dots, e_{n}}$ be a basis of the $R (B)^{n}$ , and then we could denote $Q$ by ${(f_{1}, \dots, f_{n}) \in R (B)^{n}}$ . Then we consider the subbundle $ξ = {(b, f_{1} e_{1} + \dots f_{n} e_{n}) \in B \times R (B)^{n} ∣ (f_{1}, \dots, f_{n}) \in Q}$ , then we could show that this is a bundle on $B$ such that $S (ξ) ≅ Q$ .
3.	Show that $ξ ≅ η$ if and only if $S (ξ) = S (η)$ .(Trivial)

5.

$R P^{2}$ 不能作为紧致三维流形的边界.

证明一

我们证明一个一般性结论: 若流形 $M$ 是紧致流形 $B$ 的边界, 则 $χ (M)$ 是偶数.

将 $B$ 与 $B$ 沿边界 $M$ 粘在一起得到闭流形 $\tilde{B}$ , 取 $U, V$ 分别是包含第一、二个 $B$ 的开集, 且满足 $U, V$ 同伦等价于 $B$ , 及 $U \cap V$ 同伦等价于 $M$ . 有 M-V 序列 $\dots \to H_{k} (U \cap V) = H_{k} (M) \to H_{k} (U) \oplus H_{k} (V) = H_{k} (B) \oplus H_{k} (B) \to H_{k} (\tilde{B}) \to \dots$ 故 $2 χ (B) = χ (M) + χ (\tilde{B})$ .

若 $dim M$ 是奇数, 则 $χ (M) = 0$ . 若 $dim M$ 是偶数, 则 $dim \tilde{B}$ 是奇数, 故 $χ (\tilde{B}) = 0$ , 推出 $χ (M) = 2 χ (B)$ 是偶数.

回到此题, $P^{2} = e_{0} \cup e_{1} \cup e_{2}$ 推出 $χ (P^{2}) = 1$ , 故 $P^{2}$ 不能作为三维紧致流形的边界.

证明二

我们用配边理论中的 Stiefel-Whitney class 来解决.

设 $w_{k} (T P^{2}) \in H^{k} (P^{2}, Z_{2})$ 是 $T P^{2}$ 的 Stiefel-Whitney class, $a \in H_{1} (P^{2}, Z_{2})$ 是非平凡元, 有 $w (T P^{2}) = (1 + a)^{3} = 1 + 3 a + 3 a^{2} + a^{3} = 1 + a + a^{2} .$ 故 $w_{2} (T P^{2}) = a^{2} \neq = 0$ .

取 $η \in H_{2} (P^{2}, Z_{2})$ 是生成元, 则 Stiefel-Whitney 数 $⟨ w_{2} (T P^{2}), η ⟩ = ⟨ a^{2}, η ⟩ \neq = 0.$ 由 Pontrjagin 定理: 若紧致流形 $B$ 有边界 $M$ , 则 $M$ 的所有 Stiefel-Whitney 数均为 $0$ . 故 $P^{2}$ 不能作为三维紧致流形的边界.

3Poincaré Hopf theorem

Definition 3.1. The index of vector field in $R^{n}$ .

Consider first a vector field $X$ on an open set $U \subset R^{n}$ with an isolated zero at $0 \in U$ . We can define a function $f_{X} : U ∖ {0} \to S^{n - 1}$ by $f_{X} (p) = X (p) /∥ X (p) ∥$ . If $i : S^{n - 1} \to U$ is $i (p) = εp$ , mapping $S^{n - 1}$ into $U$ , then the map $f_{X} \circ i : S^{n - 1} \to S^{n - 1}$ has a certain map degree.

It is independent of $i$ , for small $ε$ , since the maps $i_{1}, i_{2} : S^{n - 1} \to U$ corresponding to $ε_{1}$ and $ε_{2}$ will be smoothly homotopic.

The degree is called the index of $X$ at $0$ .

Lemma 3.2. If $h : U \subset R^{n} \to V \subset R^{n}$ is a diffeomorphism with $h (0) = 0$ and $X$ has an isolated zero at $0$ , then the index of $h_{*} X$ at $0$ equals the index of $X$ at $0$ .

Proof. Suppose first that $h$ is orientation preserving. Define $H : R^{n} \times [0, 1] \to R^{n}$ by $H (x, t) = {\frac{h ( t x )}{t}, d h_{0} (x), 0 < t \leq 1 t = 0.$ This is a smooth homotopy.

Each map $H_{t} : x \mapsto H (x, t)$ is clearly a diffeomorphism, $0 \leq t \leq 1$ . Note that $H_{0} = d h_{0} \in G L^{+} (n)$ , since $h$ is orientation preserving. There is also a smooth homotopy ${H_{t}}$ , $- 1 \leq t \leq 0$ with each $H_{t} \in G L^{+} (n)$ and $H_{- 1} = i d$ , since $G L^{+} (n)$ is connected. So, the map $h$ is smoothly homotopic to the identity, via maps which are diffeomorphisms.

This shows that $f_{h_{*} X}$ is smoothly homotopic to $f_{X}$ on a sufficiently small region of $R^{n} ∖ {0}$ . Hence the degree of $f_{h_{*} X} \circ i$ is the same as the degree of $f_{X} \circ i$ .

To deal with non-orientation preserving

h

, it obviously suffices to check the theorem for

h (x) = (x^{1} \dots, x^{n - 1}, x^{n})

. In this case

f_{h_{*} X} = h \circ f_{X} \circ h^{- 1},

which shows that degree of

f_{h_{*} X} \circ i

equals the degree of

f_{X} \circ i

.

$□$

As a consequence of the last lemma, we can now define the index of a vector field on a manifold.

Definition 3.3. The index of vector field on manifold.

If $X$ is a vector field on a manifold $M$ , with an isolated zero at $p \in M$ , we choose a coordinate system $(φ, U)$ with $φ (p) = 0$ , and define the index of $X$ at $p$ to be the index of $φ_{*} X$ at $0$ .

There is an amazing theorem, and I haven’t read the proof.

Theorem 3.4. A closed and connected manifold has a non vanishing vector field if and only if $χ (M) = 0$ .

4Topology

1.	Show that $SO (3)$ is a smooth manfiold, and find its fundamental group.
证明:	将 $SO (3)$ 视作空间 $R^{9}$ 的子集, 由 $A^{t} A = I$ 给出了 $6$ 个不同的多项式函数, 再辅以 $det A = 1$ 可证明其上点都是光滑的, 故该簇的光滑点全体即为 $SO (3)$ , 进而 $SO (3)$ 是光滑流形. 我们再证明 $SO (3)$ 拓扑同胚于 $R P^{3}$ . $SO (3)$ 表示 $R^{3}$ 中的旋转全体, 给定一个点 $p \in S^{2}$ , 则 $p$ 确定了一个定向的旋转轴, 按该定向确定的旋转方向旋转 $φ$ , $φ \in [0, π]$ . 注意到 $(p, 0) = (q, 0), \forall p, q \in S^{2}$ , $(p, π) = (- p, π)$ . 因此 $SO (3) = S^{2} \times [0, π] / \sim$ , 其中 $\sim$ 由前面给出. 定义映射 $f : S^{2} \times [0, π] \to R^{3}$ , $(p, φ) \to \frac{φ}{π} \cdot p$ . 当我们将 $(p, 0)$ 和 $(q, 0)$ 等同时 ( $\forall p, q \in S^{2}$ ), 得到双射 $\tilde{f} : S^{2} \times [0, π] / (p, 0) \sim (q, 0)$ 到三维欧式空间中单位球的双射. 再粘合 $(p, π)$ 和 $(- p, π)$ , 得到 $SO (3)$ 到 $R P^{3}$ 的双射, 容易验证这是同胚. 故 $SO (3) ≅ R P^{3}$ , 进而 $π_{1} (SO (3)) = π_{1} (R P^{3}) = π_{1} (R P^{2}) = Z_{2}$ .
2.	The unit tangent bundle of $S^{2}$ is the subset $T^{1} (S^{2}) = {p, v \in R^{3} ∣ ∥ p ∥ = 1, (p, v) = 0, ∥ v ∥ = 1} .$ Show that $T^{1} (S^{2})$ is a smooth submanifold of the tangent bundle $T (S^{2})$ and $T^{1} (S^{2})$ is diffeomorphic to $R P^{3}$ .
证明:	We only prove the second question. From the last problem, it suffices to show that $T^{1} (S^{2}) ≅ SO (3)$ . Firstly we choose an orthonomal frame $e_{1}, e_{2}, e_{3}$ in $R^{3}$ and for any point $(p, v)$ in $T^{1} (S^{2})$ , there is a unique element in $SO (3)$ , rotating $e_{1}$ to $p$ and $e_{2}$ to $v$ . Then we only need to show the map $T^{1} (S^{2}) \to SO (3)$ is a diffeomorhism.

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用户: Eee/Problem set on Geometry and Topology

1留言

2Milnor and Stasheff

3Poincaré Hopf theorem

4Topology