IN3.1 Integration of functions of the form m over (ax+b)

The Power Rule for Integration

One of the most important rules for integration is the power rule which says:11 Note that if $n=-1$, ${\textstyle 1/(n+1)}$ would be ${\textstyle 1/0}$ which has no meaning. $n$ can be any number (other than $-1$) - positive, negative or a fraction. Instead of saying c is a constant, we sometimes write $c\in\mathbb{R}$ which means $c$ is a real number.

Provided $n\neq-1$ then \[ \int x^{n}dx=\frac{1}{n+1}x^{n+1}+c \] where $c$ is a constant.

For example: \[\begin{align*} \int xdx & =\frac{1}{2}x^{2}+c,\quad c\in\mathbb{R}\\ \int x^{2}dx & =\frac{1}{3}x^{3}+c,\quad c\in\mathbb{R} \end{align*}\]

The question is, " How do we deal with the case when $n=-1$. That is, how do we integrate $\int\left(1/x\right)dx\,$? The answer is we define a new function as follows:

\[ \int\frac{1}{x}dx=\log_{e}\left|x\right|+c\textrm{$\quad\textrm{where c is a constant.}$ } \] This function, $\log_{e}\left|x\right|$, is called the “natural logarithm”. It is sometimes written as $\textrm{ln$\left|x\right|$ }$. Note the use of the absolute value sign. The natural logarithm is not defined for negative arguments.

We can now integrate $f(x)=m/x$ where $m$ is any constant: \[\begin{align*} \int\frac{m}{x}dx & =m\int\frac{1}{x}dx\\ & =m\log_{e}\left|x\right|+c \end{align*}\]

For example, the integral of $f(x)=\frac{5}{x}$ with respect to $x$ is $\int\frac{5}{x}dx=5\log_{e}\left|x\right|+c\quad c\in\mathbb{R}.$ There is a more general rule which covers more cases. It is:

Let $a$ , b and $m$ be constants with $a\neq0$, then \[ \int\frac{m}{ax+b}dx=\frac{m}{a}\log_{e}\left|ax+b\right|+c \] where $c$ is a constant.

Examples

Integrate $f(x)=\frac{1}{2x}\:$with respect to $x.\;$22 Here, $m=1$, $a=2$ and $b=0$.
Solution: Using the rule \[\begin{align*} \int\frac{1}{2x}dx & =\frac{1}{2}\log_{e}\left|2x\right|+c,\quad c\in\mathbb{R}. \end{align*}\]
Calculate the integral $\int\frac{2}{3x}dx$ $\;\,$33 Here, $m=2$, $a=3$ and $b=0$.
Solution: Using the rule \[\begin{align*} \int\frac{2}{3x}dx & =\frac{2}{3}\log_{e}\left|3x\right|+c,\quad c\in\mathbb{R}. \end{align*}\]
Integrate $f(x)=\frac{13}{5x-7}$ with respect to $x.\;$ 44 Here, $m=13$, $a=5$ and $b=-7$.
Solution: Using the rule \[\begin{align*} \int\frac{13}{5x-7}dx & =\frac{13}{5}\textrm{ln}\left|5x-7\right|+c,\quad c\in\mathbb{R}. \end{align*}\]
Integrate $f(x)=\frac{6}{2-3x}$ with respect to $x.\;$ 55 Here, $m=6$, $a=-3$ and $b=2$.
Solution: Using the rule \[\begin{align*} \int\frac{6}{2-3x}dx & =\frac{6}{-3}\log_{e}\left|2-3x\right|+c,\quad c\in\mathbb{R}\\ & =-2\log_{e}\left|2-3x\right|+c. \end{align*}\]
Integrate $f(x)=\frac{6}{2-3x}-\frac{2}{x+1}$ with respect to $x.\;$ 66 Here, $m=6$, $a=-3$ and $b=2$ in the first term on the right hand side and $m=-2$, $a=1$ and $b=1$in the second.
Solution: Using the rule \[\begin{align*} \int\left(\frac{6}{2-3x}-\frac{2}{x+1}\right)dx & =\frac{6}{-3}\log_{e}\left|2-3x\right|-2\log_{e}\left|x+1\right|+c,\quad c\in\mathbb{R}\\ & =-2\log_{e}\left|2-3x\right|-2\log_{e}\left|x+1\right|+c \end{align*}\]

Exercises

Calculate the following integrals

\[ \begin{array}{cccccccccccc} a) & \int\frac{1}{5x}dx & & b) & \int\frac{3}{2x}dx & & c) & \int\frac{3}{3x-5}dx & & d) & \int\frac{6}{2-7x}dx\end{array} \]

Integrate the following functions with respect to $x$:

\[ \begin{array}{cccccccccccc} a) & f(x)=x^{2}-2/x & & b) & f(x)=\frac{1}{3x-2}+\frac{3}{1-x} & & c) & f(x)=\frac{3}{3x-7}-x^{2} & & d) & f(x)=\frac{2}{5x-4}-\frac{3}{2-5x}\end{array} \]

Answers

\[ \begin{array}{cccccccccc} 1a) & \frac{1}{5}\log_{e}\left|x\right|+c & & & 1b) & \frac{3}{2}\log_{e}\left|2x\right|+c & & & 1c) & \frac{3}{2}\log_{e}\left|2x-7\right|+c\\ 1d) & -\frac{6}{7}\log_{e}\left|2-7x\right|+c\\ \\ \\ 2a) & \frac{1}{3}x^{3}-2\log_{e}\left|x\right|+c & & & 2b) & \frac{1}{3}\log_{e}\left|3x-2\right|-3\log_{e}\left|1-x\right|+c & & & 2c) & \log\left|3x-5\right|+c\\ 2d) & \frac{2}{5}\log_{e}\left|5x-4\right|+\frac{3}{2}\log_{e}\left|2-5x\right|+c \end{array} \]

The Definite Integral

Answers to all the integrals above were functions of $x$ and involved a constant. Such integrals are called indefinite integrals or antiderivatives. They do not have a specific value.

For a function $f(x)$ suppose we can write an antiderivative $F(x)=\int f(x)dx$. We then define a definite integral of a function $f(x)$ from $a$ to $b$ with respect to $x$ using the notation:77 This is known as the first fundamental theorem of calculus. \[ \int_{a}^{b}f(x)dx=\left[F(x)\right]_{a}^{b}=F(b)-F(a) \] where we assume $f(x)$ is defined for all $x$ in the interval $[a,b]$. We call $a$ the lower limit of integration and $b$ the upper limit of integration. The notation $\left[F(x)\right]_{a}^{b}$ means substitute $x=b$ and $x=a$ into $F(x)$ and then subtract the values. This gets rid of the constant of integration $c$.

For example, suppose we want to find, $\intop_{1}^{3}xdx.$ Then 88 First we find an antiderivative or indefinite integral $\int xdx+c$ and then evaluate this at the limits of integration. \[\begin{align*} F(x) & =\int xdx\\ & =\left[\frac{1}{2}x^{2}+c\right]_{x=1}^{x=3},\quad c\in\mathbb{R}\\ & =\left(\frac{1}{2}3^{2}+c\right)-\left(\frac{1}{2}1^{2}+c\right)\\ & =\left(\frac{9}{2}+c\right)-\left(\frac{1}{2}+c\right)\\ & =\frac{8}{2}\\ & =4. \end{align*}\] Note that the indefinite integral has a numerical value, in this case $4$, and there is no constant $c$.

Examples

Find the integral $\int_{1}^{2}\frac{1}{2x}dx$. 99 In this case the antiderivative is $F(x)=\frac{1}{2}\log_{e}\left|2x\right|+c,\quad c\in\mathbb{R}.$ Also remember the log laws: \[\begin{align*} \log b-\log a & =\log\frac{b}{a}\\ \log b+\log a & =\log\left(ba\right). \end{align*}\]

Solution: \[\begin{align*} \int_{1}^{2}\frac{1}{2x}dx & =\left[\frac{1}{2}\log_{e}\left|2x\right|+c\right]_{x=1}^{x=2}\\ & =\frac{1}{2}\log_{e}\left|2(2)\right|+c-\left(\frac{1}{2}\log_{e}\left|2\left(1\right)\right|+c\right)\\ & =\frac{1}{2}\log_{e}\left|4\right|-\frac{1}{2}\log_{e}\left|2\right|\\ & =\frac{1}{2}\log_{e}\left|\frac{4}{2}\right|\\ & =\frac{1}{2}\log_{e}2. \end{align*}\] Note that it is not usual to include the constant $c$ as we did in lines 1 and 2 of the solution above. The next example shows this.
Find the integral $\int_{2}^{3}\frac{13}{5x-7}dx$. 1010 In this case the antiderivative is $F(x)=\frac{13}{5}\log_{e}\left|5x-7\right|+c,\quad c\in\mathbb{R}.$

Solution: \[\begin{align*} \int_{2}^{3}\frac{13}{5x-7}dx & =\left[\frac{13}{5}\log_{e}\left|5x-7\right|\right]_{2}^{3}\\ & =\frac{13}{5}\log_{e}\left|15-7\right|-\left(\frac{13}{5}\log_{e}\left|10-7\right|\right)\\ & =\frac{13}{5}\log_{e}\left|8\right|-\left(\frac{13}{5}\log_{e}\left|3\right|\right)\\ & =\frac{13}{5}\log_{e}\frac{8}{3}. \end{align*}\]

Exercises:

Find the integral $\int_{1}^{5}\frac{2}{3x}dx$.
Calculate the integral $\int_{1}^{2}\frac{2}{3x-1}dx$
Find the integral $\int_{1}^{3}\left(x^{2}-2/x\right)dx.$ Hint: $\log_{e}1=0.$
$\int_{2}^{4}\left(\frac{2}{5x-4}-\frac{3}{2-5x}\right)dx.$ Hint: $\log_{e}1=0.$

Answers

$2\log_{e}5$ or $\log_{e}25$ (using log law $a\log_{e}x=\log_{e}x^{a}$.
$\frac{2}{3}\log_{e}3$.
$\frac{26}{3}-2\textrm{ln}3$.
$\frac{2}{5}\textrm{ln}\frac{8}{3}+\frac{3}{5}\textrm{ln}\frac{9}{4}$.

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