Reduction of Explicit ODE to First Order System

Theorem
Let $\map {x^{\paren n} } t = \map F {t, x, x', \ldots, x^{\paren {n - 1} } }$, $\map x {t_0} = x_0$ be an explicit ODE with $x \in \R^m$.

Let there exist $I \subseteq \R$ such that there exists a unique particular solution:
 * $x: I \to \R^m$

to this ODE.

Then there exists a system of first order ODEs:
 * $y' = \map {\tilde F} {t, y}$

with $y = \tuple {y_1, \ldots, y_{m n} }^T \in \R^{m n}$ such that:
 * $\tuple {\map {y_1} t, \ldots, \map {y_m} t} = \map x t$

for all $t \in I$ and $\map y {t_0} = x_0$.

Proof
Define the mappings:
 * $z_1, \ldots, z_n: I \to \R^m$

by:
 * $z_j = x^{\paren {j - 1} }$, $j = 1, \ldots, n$

Then:

This is a system of $m n$ first order ODEs.

By construction:
 * $\map {z_1} t = \map x t$

for all $t \in I$ and $\map {z_1} {t_0} = x_0$.

Therefore we can take:


 * $y = \begin {pmatrix} z_1 \\ \vdots \\ z_{n - 1} \\ z_n \end {pmatrix}, \quad \tilde F: \begin {pmatrix} z_1 \\ \vdots \\ z_n \end{pmatrix} \mapsto \begin {pmatrix} z_2 \\ \vdots \\ z_n \\ \map F {t, z_1, \ldots, z_n} \end {pmatrix}$