I suspect the following integration to be wrong. My answer is coming out to be $3/5$, but the solution says $1$.
$\int_0^1\frac{2(x+2)}{5}\,dx=\left.\frac{(x+2)^2}{5}\;\right|_0^1=1.$
Please help out. Thanks.
I suspect the following integration to be wrong. My answer is coming out to be $3/5$, but the solution says $1$.
$\int_0^1\frac{2(x+2)}{5}\,dx=\left.\frac{(x+2)^2}{5}\;\right|_0^1=1.$
Please help out. Thanks.
The integration is obtained as follows:
$\int 2\frac{x+2}{5}dx=\frac{2}{5}\int (x+2)d(x+2)=\frac{2}{5}\int udu=\frac{2}{5}\frac{u^2}{2}=\frac 1 5 (x+2)^2$
Since $\frac 1 5 (x+2)^2$ is a primitive of $2\frac{x+2}{5}$ we can use FTCII, and get
$\int 2\frac{x+2}{5}dx=\frac{(\color{red}{1}+2)^2}{5}-\frac{(\color{red}{0}+2)^2}{5}= \frac 9 5- \frac 4 5 = 1$ It seems what you did was this:
$\int 2\frac{x+2}{5}dx=\frac{(0+2)^2}{5}-\frac{(0+1)^2}{5}= \frac 4 5- \frac 1 5 = \frac 3 5$
$\left. \dfrac{(x+2)^2}5 \right \vert_0^1 = \dfrac{(1+2)^2}5 - \dfrac{(0+2)^2}5 = \dfrac{3^2}5 - \dfrac{2^2}5 = \dfrac{9}5 - \dfrac45 = \dfrac{9-4}5 = \dfrac55 = 1$
Note that we can integrate $\displaystyle \int_{x_1}^{x_2} (x+a) dx$ in seemingly two different ways.
The first method is to treat $x+a$ together as one object i.e. $\displaystyle \int (x+a) dx = \dfrac{(x+a)^2}2 + c_1$
The second method is to treat $x+a$ as two separate objects i.e. $\displaystyle \int (x+a) dx = \int x dx + \int a dx = \dfrac{x^2}2 + ax + c_2$
It might seem that both are different. However, note that the first answer can be re-written as $\dfrac{(x+a)^2}2 + c_1 = \dfrac{x^2}2 + ax + \dfrac{a^2}2 + c_1.$ Now this looks more closely like the second. The only difference in fact is that the constants are different. They are in fact related as $c_2 = c_1 + \dfrac{a^2}2$. While performing a definite integral, the constants cancel off and hence both ways should give us the same answer.
As an exercise, we will integrate what you have by treating $x$ and $2$ separately.
\begin{align} \int_0^1 \dfrac{2(x+2)}5 dx & = \dfrac25 \int_0^1 (x+2)dx = \dfrac25 \int_0^1 xdx + \dfrac25 \int_0^1 2dx = \dfrac25 \cdot \left. \dfrac{x^2}2 \right \vert_{0}^1 + \dfrac25 \cdot 2 \cdot \left(1 - 0 \right)\\ & = \dfrac25 \cdot \left(\dfrac{1^2}2 - \dfrac{0^2}2 \right) + \dfrac45 = \dfrac25 \cdot \dfrac12 + \dfrac45 = \dfrac15 + \dfrac45 = 1 \end{align}
$ \left.\frac{(x+2)^2}{5}\right|_0^1 = \frac{(1+2)^2}{5} - \frac{(0+2)^2}{5} = \frac{9}{5} - \frac{4}{5} = \frac{5}{5} = 1 $
Here's another potential approach that you will likely find useful in the future (though it isn't really necessary, here), called "$u$-substitution".
Let's put $u=x+2$. Now, $x=0$ if and only if $u=2$, and $x=1$ if and only if $u=3$. Also, $\frac{du}{dx}=\frac{d}{dx}[x+2]=1,$ and if we treat $\frac{du}{dx}$ just like any other fraction and "solve" for $dx$, we get $du=dx$. Now we'll go through and substitute everything $x$-related with the corresponding $u$-related thing, so that $\int_0^1\frac{2(x+2)}{5}\,dx=\int_2^3\frac{2u}{5}\,du=\left.\frac{u^2}{5}\right|_2^3=1.$
Now, $u$-substitutions typically require a bit more finagling than this one did, but as a preview (and an alternate approach), I think it serves its purpose.