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7.2.3.2 Example 2
\begin{align*} y^{\prime \prime \prime }-\frac {2}{3}y^{\prime \prime }+4y^{\prime }-\frac {8}{3}y & =0\\ y_{1} & =e^{\frac {2x}{3}}\end{align*}

Let \(y_{2}=y_{1}u=ue^{\frac {3}{2}x}\). Where here \(a=-\frac {2}{3},b=4,c=-\frac {8}{3}.\) Then EQ (1) becomes

\begin{align*} u^{\prime }\left ( 3y_{1}^{\prime \prime }+2ay_{1}^{\prime }+by_{1}\right ) +u^{\prime \prime }\left ( 3y_{1}^{\prime }+ay_{1}\right ) +u^{\prime \prime \prime }y_{1} & =0\\ u^{\prime }\left ( 3y_{1}^{\prime \prime }+\left ( 2\right ) \left ( -\frac {2}{3}\right ) y_{1}^{\prime }+4y_{1}\right ) +u^{\prime \prime }\left ( 3y_{1}^{\prime }-\frac {2}{3}y_{1}\right ) +u^{\prime \prime \prime }y_{1} & =0\\ u^{\prime }\left ( 3y_{1}^{\prime \prime }-\frac {4}{3}y_{1}^{\prime }+4y_{1}\right ) +u^{\prime \prime }\left ( 3y_{1}^{\prime }-\frac {2}{3}y_{1}\right ) +u^{\prime \prime \prime }y_{1} & =0 \end{align*}

But \(y_{1}=e^{\frac {2x}{3}},y_{1}^{\prime }=\frac {2}{3}e^{\frac {2x}{3}},y_{1}^{\prime \prime }=\frac {4}{9}e^{\frac {2x}{3}}\). Hence the above becomes

\begin{align*} u^{\prime }\left ( 3\left ( \frac {4}{9}e^{\frac {2x}{3}}\right ) -\frac {4}{3}\left ( \frac {2}{3}e^{\frac {2x}{3}}\right ) +4\left ( e^{\frac {2x}{3}}\right ) \right ) +u^{\prime \prime }\left ( 3\left ( \frac {2}{3}e^{\frac {2x}{3}}\right ) -\frac {2}{3}\left ( e^{\frac {2x}{3}}\right ) \right ) +u^{\prime \prime \prime }e^{\frac {2x}{3}} & =0\\ u^{\prime }\left ( \frac {4}{3}-\frac {8}{9}+4\right ) +u^{\prime \prime }\left ( 2-\frac {2}{3}\right ) +u^{\prime \prime \prime } & =0\\ \frac {40}{9}u^{\prime }+\frac {4}{3}u^{\prime \prime }+u^{\prime \prime \prime } & =0\\ 40u^{\prime }+12u^{\prime \prime }+9u^{\prime \prime \prime } & =0 \end{align*}

Let \(u^{\prime }=v\,\) then the above becomes

\[ 40v+12v^{\prime }+9v^{\prime \prime }=0 \]
This is now second order ode. The solution for \(v\) can be found to be
\[ v=c_{1}e^{\frac {-2x}{3}}\sin \left ( 2x\right ) +c_{2}e^{-\frac {2x}{3}}\cos \left ( 2x\right ) \]
But \(u^{\prime }=v\), then
\[ u=\int vdx+c_{3}\]
We can choose \(c_{3}=0\,\). Hence
\begin{align*} u & =\int c_{1}e^{\frac {-2x}{3}}\sin \left ( 2x\right ) +c_{2}e^{-\frac {2x}{3}}\cos \left ( 2x\right ) dx\\ & =-\frac {9e^{-\frac {2x}{3}}}{20}\left ( \left ( c_{1}+\frac {c_{2}}{3}\right ) \cos \left ( 2x\right ) +\frac {1}{3}\left ( c_{1}-3c_{2}\right ) \sin \left ( 2x\right ) \right ) \\ & =e^{-\frac {2x}{3}}\left ( c_{3}\cos \left ( 2x\right ) +c_{4}\sin \left ( 2x\right ) \right ) \end{align*}

Where in the last step above, constants were combined to make new constants. Renaming constants, the above becomes

\[ u=e^{-\frac {2x}{3}}\left ( c_{1}\cos \left ( 2x\right ) +c_{2}\sin \left ( 2x\right ) \right ) \]
Since second solution is \(y_{2}=y_{1}u\) then we have
\begin{align*} y_{2} & =y_{1}u\\ & =e^{\frac {2x}{3}}\left ( e^{-\frac {2x}{3}}\left ( c_{1}\cos \left ( 2x\right ) +c_{2}\sin \left ( 2x\right ) \right ) \right ) \\ & =c_{1}\cos \left ( 2x\right ) +c_{2}\sin \left ( 2x\right ) \end{align*}

Hence the solution is

\begin{align*} y & =c_{3}y_{1}+c_{4}y_{2}\\ & =c_{3}e^{\frac {2x}{3}}+c_{4}\left ( c_{1}\cos \left ( 2x\right ) +c_{2}\sin \left ( 2x\right ) \right ) \\ & =c_{3}e^{\frac {2x}{3}}+c_{1}\cos \left ( 2x\right ) +c_{2}\sin \left ( 2x\right ) \end{align*}

Where in the last step above we just merged and renamed constants.

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