3.1.6 The linearized symmetry condition
This was derived in the introduction
\begin{equation} \fbox {$\eta _x+\omega \left ( \eta _y-\xi _x\right ) -\omega ^2\xi _y-\omega _x\xi -\omega _y\eta =0$} \tag {14}\end{equation}
The above equation (14) is what is used to determine
\(\xi ,\eta \). It is the
linearized symmetry
condition. There is an additional constraint not mentioned above which is
\[ \bar {x}_{x}\bar {y}_{y}\neq \bar {x}_{y}\bar {y}_{x}\]
The restricted
form of (14) is
\[ \chi _{x}+\chi _{y}\omega -\chi \omega _{y}=0 \]
An important property is the following. Given any
\[ \xi =A,\eta =B \]
Then we can
always write the above as
\[ \xi =0,\eta =B-\omega A \]
So that
\(\xi =0\) can always be used if needed to simplify some
things.
After finding \(\xi ,\eta \) from (14), the question now becomes is how to use them to solve the original
ODE?