Necessary and Sufficient Condition for First Order System to be Field for Second Order System

Theorem
Let $\mathbf y$, $\mathbf f$, $\boldsymbol \psi$ be N-dimensional vectors.

Let $\boldsymbol\psi$ be continuously differentiable.

Then $\forall x \in \closedint a b$ the first-order system of differential equations:


 * $\mathbf y' = \map {\boldsymbol \psi} {x, \mathbf y}$

is a field for the second-order system


 * $\mathbf y'' = \map {\mathbf f} {x, \mathbf y, \mathbf y'}$

$\boldsymbol \psi$ satisfies :


 * $\displaystyle \frac {\partial \boldsymbol \psi} {\partial x} + \sum_{i \mathop = 1}^N \frac {\partial \boldsymbol \psi} {\partial y_i} \psi_i = \map {\mathbf f} {x, \mathbf y, \boldsymbol \psi}$

That is, every solution to Hamilton-Jacobi system is a field for the original system.

Necessary condition
Differentiate the first-order system $x$:

This can be rewritten as the following system of equations:


 * $\mathbf y'' = \map {\mathbf f} {x, \mathbf y, \mathbf y'}$


 * $\displaystyle \frac {\partial \boldsymbol \psi} {\partial x} + \sum_{i \mathop = 1}^N \frac {\partial \boldsymbol \psi} {\partial y_i} \psi_i = \map {\mathbf f} {x, \mathbf y, \mathbf y'}$

By assumption, the first-order system is valid in $\closedint a b$.

For the second-order system to be valid in the same interval, the corresponding Hamilton-Jacobi equation has to hold as well.