Systems of ODEs: Difference between revisions
From Rice Wiki
Line 59: | Line 59: | ||
First order systems are more general than higher order scalars, in that not all first order systems can be represented as a scalar. | First order systems are more general than higher order scalars, in that not all first order systems can be represented as a scalar. | ||
= Initial value problem = | |||
If P(t) and '''g'''(t) are continuous, then the IVP | |||
<math> | |||
\begin{cases} | |||
\vec{x}'=P\vec{x}+g\\ | |||
\vec{x}=\vec{x}^{(0)} | |||
\end{cases} | |||
</math> | |||
has a solution |
Revision as of 14:14, 10 June 2024
An nxn system of ODEs looks like the following
In vector form, the same equation can be written as
Non-linear ODEs are very complicated (like chaos theory, three body problem, etc.). This page will focus entirely on linear systems, which can be expressed as
where P is the nxn coefficient matrix.
Reduce order
Given a higher order ODE, one can write it as a system of first order ODEs.
For example, take the following second order linear ODE:
You can rewrite it as the following:
First order systems are more general than higher order scalars, in that not all first order systems can be represented as a scalar.
Initial value problem
If P(t) and g(t) are continuous, then the IVP
has a solution