Solve the differential equation using Taylor-series expansion:
$ \frac{dy}{dx} = x + y + xy \\ y (0) = 1 $ to get value of $y$ at $x = 0.1$ and $x = 0.5$. Use terms through $x^5$.
Solve the differential equation using Taylor-series expansion:
$ \frac{dy}{dx} = x + y + xy \\ y (0) = 1 $ to get value of $y$ at $x = 0.1$ and $x = 0.5$. Use terms through $x^5$.
The approach that I have seen taken when asked to determine the solution using Taylor's Theorem is as follows.
We have, from Taylor's Theorem, $y(x)=y(0)+y'(0)x+\frac{y''(0)}{2}x^2+\frac{y^{(3)}(0)}{6}x^3+\ldots$ which we need to solve for the respective coefficients.
We are given $y(0)=1$. When $x=0$, the ODE must be satisfied. Then we must have $ y'(0) = 0+1+0\cdot1=1.$ Differentiating the ODE we get $\frac{d^2y}{dx^2}=1+\frac{dy}{dx}+y+x\frac{dy}{dx}.$ Using this, we get that, at $x=0$, $y''(0)=1+1+1+0\cdot1=3.$
Then, we have $y(x)=1+x+\frac{3}{2}x^2+\frac{y^{(3)}(0)}{6}x^3+\ldots$ Continuing in this fashion, you can get the value of $y^{(3)}(0)$ and higher derivatives at $x=0$, thus giving a solution to the original ODE.
Once you have the required terms, you can evaluate the function at $x=0.1$ and $x=0.5$.
Suppose that $y$ has the Taylor series expansion about $x=0$ given by $y=a_0+a_1x+a_2x^2+a_3x^3+a_4x^4+a_5x^5+\cdots.$ Because $y(0)=1$, we have $a_0=1$. Differentiate. We get $\frac{dy}{dx}=a_1+2a_2x+3a_3x^2+4a_4x^3+5a_5x^4+\cdots.\tag{$1$}$ Also, $\begin{align}x+y+xy&=x+(1+a_1x+a_2x^2+a_3x^3+a_4x^4+a_5x^5+\cdots)\\&+(x+a_1x^2+a_2x^3+a_3x^4+a_4x^5+\cdots).\end{align}$ In the expression above, gather like powers of $x$ together. We get $x+y+xy=1+(2+a_1)x+(a_1+a_2)x^2+(a_2+a_3)x^3+(a_4+a_5)x^4+\cdots.\tag{$2$}$ The expansions $(1)$ and $(2)$ must be identical. It follows that they have the same constant term, that is, that $a_1=1$.
The coefficients of $x$ in $(1)$ and $(2)$ must match. It follows that $2a_2=2+a_1=3$, and therefore $a_2=\frac{3}{2}$.
The coefficients of $x^2$ must match. It follows that $3a_3=a_1+a_2=\frac{5}{2}$, and therefore $a_3=\frac{5}{6}$.
Continue, finding $a_4$ and $a_5$. You have not been asked to find coefficients beyond $a_5$.
For the numerical calculations, just substitute the given values of $x$ in the expression $1+a_1x+a_2x^2+a_3x^3+a_4x^4+a_5x^5$, using the values of the $a_i$ that we have found.