Systems of ODEs: Difference between revisions

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</math>
</math>


where P is the coefficient matrix.
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:
 
<math>
y'' + py' + qy = g
</math>
 
You can rewrite it as the following:
 
<math>
\begin{pmatrix}
y_1' \\
y_2'
\end{pmatrix}
=
\begin{pmatrix}
0 & 1 \\
-q & -p
\end{pmatrix}
\begin{pmatrix}
y_1 \\
y_2
\end{pmatrix}
+
\begin{pmatrix}
0 \\
g
\end{pmatrix}
</math>
 
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 unique solution
 
If the results are [[linear independence (functions)|linearly independent]], it is a fundamental set of solutions for the ODE, i.e. they span the entire solution space, where all solutions can be described as
 
<math>
\vec{x}(t)=c_1\vec{x}^{(1)}+\ldots+c_k\vec{x}^{(k)}=X\vec{c}
</math>
 
Its [[Wronskian]] would be correspondingly defined as the determinant.
 
= Classifications =
* [[Homogeneous linear systems: constant coefficients]]

Latest revision as of 15:01, 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 unique solution

If the results are linearly independent, it is a fundamental set of solutions for the ODE, i.e. they span the entire solution space, where all solutions can be described as

Its Wronskian would be correspondingly defined as the determinant.

Classifications