Riemannian Geometry/Parametrisation of curves

Definition (regular curve):

Let $(M,g)$ be a Riemannian manifold. A curve $\gamma :I\to M$ is called regular if and only if for all $t\in {\overset {\circ }{I}}$ , we have

\gamma '(t)\neq 0

.

Proposition (existence of parametrisation by arc-length of regular curves):

Let $\gamma :I\to \mathbb {R} ^{n}$ be a regular, continuously differentiable curve, where $I=(a,b)\subseteq \mathbb {R}$ is an open, connected interval. Then there exists a different open, connected interval $J=(c,d)\subseteq \mathbb {R}$ and a continuously differentiable bijective function $\rho :J\to I$ , such that

\forall t\in J:\|(\gamma \circ \rho )'(t)\|=1

.

Proof: By the chain rule, we have

(\gamma \circ \rho )'(t)=\gamma '(\rho (t))\rho '(t)

for all $t\in J$ . Hence, the equation $\|(\gamma \circ \rho )'(t)\|=1$ becomes equivalent to

|\rho '(t)|={\frac {1}{\|\gamma '(\rho (t))\|}}

,

and the existence of a solution to the latter equation implies the existence of a solution to the former. Moreover, it suffices to solve

\rho '(t)={\frac {1}{\|\gamma '(\rho (t))\|}}

,

because the right hand side will always be positive. From Peano's theorem, we may infer the existence of a $\rho$ satisfying the given identity on a neighbourhood of $0$ , where we impose the initial condition $\rho (0)=t_{0}$ , where $t_{0}\in J$ is arbitrary. Then we may extend the solution to the maximum interval, $\Box$

Proposition (existence of regular modification):

Let $\gamma :[0,1]\to \mathbb {R} ^{n}$ be a curve which is twice continuously differentiable. Then there exists a modified curve ${\tilde {\gamma }}:[0,c]\to \mathbb {R} ^{n}$ , defined on an interval $[0,c]$ , where $c>0$ is some positive number, such that

\forall t\in [0,c]:\|{\tilde {\gamma }}'(t)\|=1

.

Proof: Define

U:=\{t\in [0,1]|\gamma '(t)\neq 0\}=(\gamma ')^{-1}(\mathbb {R} ^{n}\setminus \{0\})

;

by continuity of $\gamma '$ , this is an open subset of $[0,1]$ . It decomposes into at most countably many connected components

\bigcup _{n\in \mathbb {N} }U_{n}

, where

U_{n}=(a_{n},b_{n})

for all

n\in \mathbb {N}

;

when there are only finitely many connected components, say $N$ many, we will set $a_{n}=b_{n}=1$ for $n>N$ by convention.

Now fix an $n$ such that $a_{n}<b_{n}$ . We would like to modify $\gamma |_{(a_{n},b_{n})}$ such that for all points $t$ in the domain of the modification (whatever that may be), the absolute value of the derivative of the modification equals $1$ . By induction on $n$ , we assume that we have already found a modification ${\tilde {\gamma }}_{n-1}:[0,c_{n}]\to \mathbb {R} ^{n}$ that traverses $\Box$

Definition (parametrisation by arc-length):

Proposition (characterisation of parametrisation by arc-length):