1.3.9 Example 9. \(xy^{\prime }+y=3+x\)
\begin{equation} xy^{\prime }+y=3+x \tag {1}\end{equation}
This is same as example 1, but with nonzero on RHS. The solution is
\(y=y_{h}+y_{p}\). Where
\(y_{h}\) was found
above as
\[ y_{h}=\frac {a_{0}}{x}\]
To find
\(y_{p}\) we will use the balance equation, EQ (*) found in the first example
when finding
\(y_{h}\). We just need to rename
\(a_{0}\) to
\(c_{0}\) and add the
\(x\) on the right side of the balance
equation.
\[ \left ( r+1\right ) c_{0}x^{r}=3+x \]
For each term on the right side, there is different balance equation. Hence we
have
\begin{align} \left ( r+1\right ) c_{0}x^{r} & =3\tag {2}\\ \left ( r+1\right ) c_{0}x^{r} & =x \tag {3}\end{align}
Each one equation above, gives different \(y_{p}\) then at the end we will add them all. Starting
with (2)
\[ \left ( r+1\right ) c_{0}x^{r}=3 \]
Hence
\(r=0\), therefore
\(\left ( r+1\right ) c_{0}=3\) or
\(c_{0}=3\). Hence the first particular solution is
\(y_{p_{1}}=3\). Now we will look at
(3)
\[ \left ( r+1\right ) c_{0}x^{r}=x \]
Hence
\(r=1\), therefore
\(\left ( r+1\right ) c_{0}=1\) or
\(c_{0}=\frac {1}{2}\). Hence the second particular solution is
\(y_{p_{2}}=\frac {1}{2}x\). Adding all the
particular solutions gives
\[ y_{p}=2+\frac {1}{2}x \]
The complete solution is
\begin{align*} y & =y_{h}+y_{p}\\ & =\frac {a_{0}}{x}+3+\frac {1}{2}x \end{align*}