Differentiable Manifolds/Diffeomorphisms and related vector fields

Differentiable Manifolds
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Diffeomorphisms

We shall now define the notions of homeomorphisms and diffeomorphisms for mappings between manifolds.

Definition 6.1:

Let $M$ be a manifold of class ${\mathcal {C}}^{n}$ , where as usual $n\in \mathbb {N} _{0}\cup \{\infty \}$ , and let $N$ be a manifold of class ${\mathcal {C}}^{k}$ , where also $k\in \mathbb {N} _{0}\cup \{\infty \}$ . A function $\psi :M\to N$ is called a homeomorphism iff

it is bijective
both itself and $\psi ^{-1}$ are continuous

Definition 6.2:

Let $M$ be a manifold of class ${\mathcal {C}}^{n}$ , where $n\in \mathbb {N} _{0}\cup \{\infty \}$ , and let $N$ be a manifold of class ${\mathcal {C}}^{k}$ , where also $k\in \mathbb {N} _{0}\cup \{\infty \}$ . Let $j\in \mathbb {N} \cup \{\infty \}$ . A function $\psi :M\to N$ is called a diffeomorphism of class ${\mathcal {C}}^{j}$ iff

it is bijective
both itself and $\psi ^{-1}$ are differentiable of class ${\mathcal {C}}^{j}$

The rank of the differential

Definition 6.3:

Let $d,b\in \mathbb {N}$ , $M$ be a $d$ -dimensional manifold of class ${\mathcal {C}}^{n}$ , $N$ be a $b$ -dimensional manifold of class ${\mathcal {C}}^{k}$ , $U\subseteq M$ be open, $p\in U$ and $\psi :U\to N$ differentiable of class ${\mathcal {C}}^{m}$ . The rank of $d\psi _{p}$ is defined as

{\text{rank }}d\psi _{p}:=\dim {\text{Im }}d\psi _{p}

.

The dimension of ${\text{Im }}d\psi _{p}$ is well-defined since $d\psi _{p}$ is a linear function, which is why it's image is a vector space; further, it is a vector subspace of $T_{\psi (p)}N$ , which is a $b$ -dimensional vector space, which is why it has finite dimension.

Theorem 6.4:

Let $M$ be a $d$ -dimensional manifold of class ${\mathcal {C}}^{n}$ and $N$ be a $b$ -dimensional manifold of class ${\mathcal {C}}^{k}$ .

Related vector fields

Definition 6.3:

Let $M$ be a manifold of class ${\mathcal {C}}^{n}$ , where $n\in \mathbb {N} _{0}\cup \{\infty \}$ , let $N$ be a manifold of class ${\mathcal {C}}^{k}$ , where also $k\in \mathbb {N} _{0}\cup \{\infty \}$ , and let $\psi :M\to N$ be differentiable of class ${\mathcal {C}}^{j}$ , where also $j\in \mathbb {N} \cup \{\infty \}$ . We call $\mathbf {V} \in {\mathfrak {X}}(M)$ and $\mathbf {W} \in {\mathfrak {X}}(N)$ $\psi$ -related iff

\forall p\in M:\mathbf {W} (\psi (p))=d\psi _{p}(\mathbf {V} (p))

Theorem 6.4:

Let $M$ be a manifold of class ${\mathcal {C}}^{n}$ , where $n\in \mathbb {N} _{0}\cup \{\infty \}$ , let $N$ be a manifold of class ${\mathcal {C}}^{k}$ , where also $k\in \mathbb {N} _{0}\cup \{\infty \}$ , let $\psi :M\to N$ be a diffeomorphism of class ${\mathcal {C}}^{j}$ , where also $j\in \mathbb {N} \cup \{\infty \}$ , and let $\mathbf {V} \in {\mathfrak {X}}(M)$ . Then $\mathbf {W}$

\mathbf {W} (q)=d\psi _{\psi ^{-1}(q)}(\mathbf {V} (\psi ^{-1}(q)))

is the unique vector field such that $\mathbf {V}$ and $\mathbf {W}$ are $\psi$ -related.

Proof:

1. We show that $\mathbf {V}$ and $\mathbf {W}$ are $\psi$ -related.

Let $p\in M$ be arbitrary. Then we have:

\mathbf {W} (\psi (p))=d\psi _{\psi ^{-1}(\psi (p))}(\mathbf {V} (\psi ^{-1}(\psi (p))))=d\psi _{p}(\mathbf {V} (p))

2. We show that there are no other vector fields besides $\mathbf {W}$ which are $\psi$ -related to $\mathbf {V}$ .

Let $\mathbf {Z}$ be also contained in ${\mathfrak {X}}(N)$ such that $\mathbf {V}$ and $\mathbf {Z}$ are $\psi$ -related. We show that $\mathbf {Z} =\mathbf {W}$ , thereby excluding the possibility of a different to ${\mathcal {X}}$ $\psi$ -related vector field.

Indeed, for every $q\in N$ we have:

Due to the bijectivity of $\psi$ , there exists a unique $p\in M$ such that $\psi (p)=q$ , and we have $p=\psi ^{-1}(q)$ . Therefore, and since $\mathbf {Z}$ was required to be $\psi$ -related to $\mathbf {V}$ :

\mathbf {Z} (q)=\mathbf {Z} (\psi (p))=d\psi _{p}(\mathbf {V} (p))=d\psi _{\psi ^{-1}(q)}(\mathbf {V} (\psi ^{-1}(q)))=\mathbf {W} (q)

Theorem 6.5:

Let $M$ be a manifold of class ${\mathcal {C}}^{n}$ , where $n\in \mathbb {N} _{0}\cup \{\infty \}$ , let $N$ be a manifold of class ${\mathcal {C}}^{k}$ , where also $k\in \mathbb {N} _{0}\cup \{\infty \}$ , let $\psi :M\to N$ be a diffeomorphism of class ${\mathcal {C}}^{j}$ , where also $j\in \mathbb {N} \cup \{\infty \}$ . If $\mathbf {V}$ is differentiable of class ${\mathcal {C}}^{m}$ where $m\in N$ and $m\leq j$ , then the unique $\psi$ -related vector field

\mathbf {W} (p)=d\psi _{\psi ^{-1}(q)}(\mathbf {V} (\psi ^{-1}(q)))

is differentiable of class ${\mathcal {C}}^{m}$ .

Proof:

Let $\vartheta \in {\mathcal {C}}^{m}(N)$ . Inserting a few definitions from chapter 2, we obtain

{\begin{aligned}\mathbf {W} \vartheta (p)&=(d\psi _{\psi ^{-1}(p)}(\mathbf {V} (\psi ^{-1}(p))))(\vartheta )\\&=(\mathbf {V} (\psi ^{-1}(p))\circ \psi ^{*})(\vartheta )\\&=\mathbf {V} (\psi ^{-1}(p))(\vartheta \circ \psi )\\&=\mathbf {V} (\vartheta \circ \psi )(\psi ^{-1}(p))\\&=\left(\left(\psi ^{-1}\right)^{*}\mathbf {V} (\vartheta \circ \psi )\right)(p)\\\end{aligned}}

, and therefore

\mathbf {W} \vartheta =\left(\psi ^{-1}\right)^{*}\mathbf {V} (\vartheta \circ \psi )

Since $\psi$ is differentiable of class ${\mathcal {C}}^{j}$ and $j\geq m$ , $\psi$ is also differentiable of class ${\mathcal {C}}^{m}$ . Further, the function

\mathbf {V} (\vartheta \circ \psi )

is differentiable of class ${\mathcal {C}}^{m}$ , because $\mathbf {V}$ is differentiable of class ${\mathcal {C}}^{m}$ . Due to lemma 2.17, it follows that also

\mathbf {W} \vartheta =\left(\psi ^{-1}\right)^{*}\mathbf {V} (\vartheta \circ \psi )

is differentiable of class ${\mathcal {C}}^{m}$ , and therefore, due to the definition of differentiability of vector fields, so is $\mathbf {W}$ . $\Box$

Differentiable Manifolds
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