2.6 Exponential functions | Functions

2.6 Exponential functions (EMCFF)

Revision of exponents

An exponent indicates the number of times a certain number (the base) is multiplied by itself. The exponent, also called the index or power, indicates the number of times the multiplication is repeated. For example, \(\text{10}^{3} = 10 \times 10 \times 10 = \text{1 000}\).

Graphs of the exponential function \(f(x) = b^{x}\)

The value of \(b\) affects the direction of the graph:

If \(b > 1\), \(f(x)\) is an increasing function.
If \(0 < b < 1\), \(f(x)\) is a decreasing function.
If \(b \leq 0\), \(f(x)\) is not defined.

\(y = b^{x}\)	\(b > 1\)	\(0 < b < 1\)	\(b \leq 0\)
			Not defined

Inverse of the function \(y=b^{x}\) (EMCFG)

Determining the inverse

Function	Type of function	Inverse:	Inverse:
		interchange \(x\) and \(y\)	make \(y\) the subject
\(y = \frac{x}{3} + 10\)
\(y = \frac{x^{2}}{3}\)
\(y = (10)^{x}\)
\(y = \left( \frac{1}{3} \right)^{x}\)

Consider the exponential function

\[y = b^{x}\]

To determine the inverse of the exponential function, we interchange the \(x\)- and \(y\)-variables:

\[x = b^{y}\]

For straight line functions and parabolic functions, we could easily manipulate the inverse to make \(y\) the subject of the formula. For the inverse of an exponential function, however, \(y\) is the index and we do not know a method of solving for the index.

To resolve this problem, mathematicians defined the logarithmic function. The logarithmic function allows us to rewrite the expression \(x = b^{y}\) with \(y\) as the subject of the formula:

\[y = \log_{b}{x}\]

This means that \(x = b^{y}\) is the same as \(y = \log_{b}{x}\) and both are the inverse of the exponential function \(y = b^{x}\).

Logarithms (EMCFH)

Logarithm: If \(x = {b}^{y}\), then \(y = {\log}_{b}\left(x\right)\), where \(b>0\), \(b \ne 1\) and \(x>0\).

Note that the brackets around the number \((x)\) are not compulsory, we use them to avoid confusion.

The logarithm of a number \((x)\) with a certain base \((b)\) is equal to the exponent \((y)\), the value to which that certain base must be raised to equal the number \((x)\).

For example, \(\log_{2}\left(8\right)\) means the power of \(\text{2}\) that will give \(\text{8}\). Since \({2}^{3}=8\), we see that \({\log}_{2}\left(8\right)=3\). Therefore the exponential form is \({2}^{3}=8\) and the logarithmic form is \({\log}_{2}{8}=3\).

Restrictions on the definition of logarithms

\[\begin{array}{rll} \text{Restriction:}& & \text{Reason: } \\ & & \\ b > 0 & & \text{If } b \text{ is a negative number, then } b^{y} \text{ will oscillate between:} \\ & & \text{positive values if } y \text{ is even } \\ & & \text{negative values if } y \text{ is odd } \\ & & \\ b \ne 1 & & \text{Since } 1^{\text{(any value)}} = 1 \\ & & \\ x > 0 & & \text{Since } \text{(positive number)}^{\text{(any value)}} > 0 \end{array}\]

Exponential and logarithmic form

Discuss the following statements and determine whether they are true or false:

\(p = a^{n}\) is the inverse of \(p = \log_{a}{n}\).
\(y = 2^{x}\) is a one-to-one function, therefore \(y = \log_{2}{x}\) is also a one-to-one function.
\(x = \log_{5}{y}\) is the inverse of \(5^{x} = y\).
\(k = b^{t}\) is the same as \(t = \log_{b}{k}\).

To determine the inverse function of \(y=b^{x}\):

\[\begin{array}{rll} &(1) \quad \text{Interchange } x \text{ and } y: & x = b^{y} \\ &(2) \quad \text{Make } y \text{ the subject of the equation}: & y = \log_{b}{x} \end{array}\]

Therefore, if we have the exponential function \(f(x) = b^{x}\), then the inverse is the logarithmic function \(f^{-1}(x) = \log_{b}{x}\).

The “common logarithm” has a base \(\text{10}\) and can be written as \(\log_{10}{x} = \log{x}\). In other words, the \(\log\) symbol written without a base is interpreted as the logarithm to base \(\text{10}\). For example, \(\log{\text{25}} = \log_{10}{\text{25}}\).

Video: 28BR

Worked example 10: Exponential form to logarithmic form

Write the following exponential expressions in logarithmic form and express each in words:

\(5^{2} = 25\)
\(10^{-3} = \text{0,001}\)
\(p^{x} = q\)

Determine the inverse of the given exponential expressions

Remember: \(m = a^{n}\) is the same as \(n = \log_{a}{m}\).

\(2 = \log_{5}{25}\)
\(-3 = \log_{10}{(\text{0,001})}\)
\(x = \log_{p}{q}\)

Express in words

\(\text{2}\) is the power to which \(\text{5}\) must be raised to give the number \(\text{25}\).
\(-\text{3}\) is the power to which \(\text{10}\) must be raised to give the decimal number \(\text{0,001}\).
\(x\) is the power to which \(p\) must be raised to give \(q\).

Worked example 11: Logarithmic form to exponential form

Write the following logarithmic expressions in exponential form:

\(\log_{2}{128} = 7\)
\(-2 = \log_{3}{\left( \frac{1}{9} \right)}\)
\(z = \log_{w}{k}\)

Determine the inverse of the given logarithmic expressions

For \(n = \log_{a}{m}\), we can write \(m = a^{n}\).

\(2^{7} = \text{128}\)
\(3^{-2} = \frac{1}{9}\)
\(w^{z} = k\)

temp text

Finding the inverse of \(y=b^{x}\)

Textbook Exercise 2.6

\(16 = 2^{4}\)

\(4 = \log_{2}{16}\)

\(3^{-5} = \frac{1}{243}\)

\(-5 = \log_{3}{\left( \frac{1}{243} \right) }\)

\((\text{1,7})^{3} = \text{4,913}\)

\(3 = \log_{\text{1,7}}{(\text{4,913})}\)

\(y = 2^{x}\)

\(x = \log_{2}{y}\)

\(q = 4^{5}\)

\(\log_{4} q = 5\).

\(4 = y^{g}\)

\(\log_{y} 4 = g\).

\(9 = (x -4)^{p}\)

\(\log_{(x - 4)} 9 = p\).

\(3 = m^{(a + 4)}\)

\(\log_{m} 3 = a + 4\).

\(\log_{2}{32} = 5\)

The logarithm of \(\text{32}\) to base \(\text{2}\) is equal to \(\text{5}\).

\(2^{5} = 32\)

\(\log{\frac{1}{1000}} = -3\)

The logarithm of \(\frac{1}{1000}\) to base \(\text{10}\) is equal to \(-\text{3}\).

\(10^{-3} = \frac{1}{1000}\)

\(\log{\text{0,1}} = -1\)

The logarithm of \(\text{0,1}\) to base \(\text{10}\) is equal to \(-\text{1}\).

\(10^{-1} = \text{0,1}\)

\(\log_{d}{c} = b\)

The logarithm of \(c\) to base \(d\) is equal to \(b\).

\(d^{b} = c\)

\(\log_{5}{1} = 0\)

The logarithm of \(\text{1}\) to base \(\text{5}\) is equal to \(\text{0}\).

\(5^{0} = 1\)

\(\log_{3}{\frac{1}{81}} = -4\)

The logarithm of \(\frac{1}{81}\) to base \(\text{3}\) is equal to \(-\text{4}\).

\(3^{-4} = \frac{1}{81}\)

\(\log{100}\)

\begin{align*} \text{Let } \log{100} &= m \\ 10^{m} &= 100 \\ &= 10^{2} \\ \therefore m &= 2 \\ \therefore \log{100} &= 2 \end{align*}

The logarithm of \(\text{100}\) to base \(\text{10}\) is \(\text{2}\).

\(\log_{\frac{1}{2}}{16}\)

\begin{align*} \text{Let } \log_{\frac{1}{2}}{16} &= y \\ \therefore \left( \frac{1}{2} \right)^{y} &= 16 \\ \therefore 2^{-y}&= 2^{4} \\ -y &= 4 \\ \therefore y &= -4 \end{align*}

The logarithm of \(\text{16}\) to base \(\frac{1}{2}\) is \(-\text{4}\).

Logarithm bases (EMCFJ)

From the definition of a logarithm we know that the base of a logarithm must be a positive number and it cannot be equal to \(\text{1}\). The value of the base influences the value of the logarithm. For example, \({\log}_{2}2\) is not the same as \({\log}{2}\) and \({\log}_{f}{11}\) is not the same as \({\log}_{g}{11}\), (\(f \ne g\)).

We often calculate the “common logarithm”, which has a base \(\text{10}\) and can be written as \(\log_{10}{x} = \log{x}\). For example, \(\log{8} = \log_{10}{8}\).

The “natural logarithm”, which has a base \(e\) (an irrational number between \(\text{2,71}\) and \(\text{2,72}\)), can be written as \(\log_{e}{x} = \ln{x}\). For example, \(\log_{e}{5} = \ln{5}\).

Special logarithmic values

\(\log_{a}{1} = 0\) \begin{align*} \text{Given the exponential form } a^{n} &= x \\ \text{we define the logarithmic function } \log_{a}{x} &= n \\ \text{So then for } a^{0} &= 1 \\ \text{we can write } \log_{a}{1} &= 0 \end{align*}
\(\log_{a}{a} = 1\) \begin{align*} \text{From the general exponential form } a^{n} &= x \\ \text{we define the logarithmic function } \log_{a}{x} &= n \\ \text{Since } a^{1} &= a \\ \text{we can write } \log_{a}{a} &= 1 \end{align*}

Laws of logarithms (EMCFK)

In earlier grades, we used the following exponential laws for working with exponents:

\({a}^{m} \times {a}^{n}={a}^{m+n}\)
\(\frac{{a}^{m}}{{a}^{n}}={a}^{m-n}\)
\({\left(ab\right)}^{n}={a}^{n}{b}^{n}\)
\({\left(\frac{a}{b}\right)}^{n}=\frac{{a}^{n}}{{b}^{n}}\)
\({\left({a}^{m}\right)}^{n}={a}^{mn}\)

where \(a > 0\), \(b > 0\) and \(m, n \in ℤ\).

The logarithmic laws are based on the exponential laws and make working with logarithms much easier.

Logarithmic laws:

\(\log_{a}{x^{b}} = b \log_{a}{x} \qquad (x > 0)\)
\(\log_{a}{x} = \frac{\log_{b}{x}}{\log_{b}{a}} \qquad (b > 0 \text{ and } b \ne 1)\)
\(\log_{a}{xy} = \log_{a}{x} + \log_{a}{y} \qquad (x > 0 \text{ and } y > 0)\)
\(\log_{a}{\frac{x}{y}} = \log_{a}{x} - \log_{a}{y} \qquad (x > 0 \text{ and } y > 0)\)

The last two logarithmic laws in the list above are not covered in this section. They are discussed at the end of the chapter and are included for enrichment only.

IMPORTANT: PROOFS ARE NOT REQUIRED FOR EXAMS

Logarithmic law:

\[\log_{a}{x^{b}} = b \log_{a}{x} \qquad (x > 0 )\]

\begin{align*} \text{Let } {\log}_{a}{x} &= m \ldots (1)\qquad (x > 0 ) \\ \therefore x &= a^{m} \\ \therefore (x)^{b} &= \left( a^{m} \right)^{b} \\ \therefore x^{b} &= a^{bm} \\ \text{Change to logarithmic form: }\log_{a}\left(x^{b}\right) &= bm \\ \text{And subst}: \quad m &= {\log}_{a}{x} \\ \therefore {\log}_{a}{x^{b}} &= b{\log}_{a}{x} \end{align*}

In words: the logarithm of a number which is raised to a power is equal to the value of the power multiplied by the logarithm of the number.

Worked example 12: Applying the logarithmic law \(\log_{a}{x^{b}} = b \log_{a}{x}\)

Determine the value of \(\log_{3}{{27}^{4}}\).

Use the logarithmic law to simplify the expression

\begin{align*} \log_{3}{{27}^{4}} &= 4 \log_{3}{{27}}\\ &= 4\log_{3}{{3}^{3}} \\ &= (4 \times 3) \log_{3}{3}\\ &= 12 (1) \\ &= 12 \end{align*}

Write the final answer

\(\log_{3}{{27}^{4}} = 12\)

Special case:

\[\log_{a}{\sqrt[b]{x}} = \frac{\log_{a}{x}}{b} \qquad (x > 0 \text{ and } b > 0 )\]

The following is a special case of the logarithmic law \(\log_{a}{x^{b}} = b \log_{a}{x}\):

\begin{align*} \log_{a}{\sqrt[b]{x}} &= \log_{a}{{x}^{\frac{1}{b}}} \\ &= \frac{1}{b} \log_{a}{x} \\ &= \frac{\log_{a}{x}}{b} \end{align*}

Video: 28CC

Applying the logarithmic law: \(\log_{a}{x^{b}} = b \log_{a}{x}\)

Textbook Exercise 2.7

\(\log_{8}{{10}^{10}}\)

\[\log_{8}{{10}^{10}} = 10 \log_{8}{10}\]

\(\log_{16}{{x}^{y}}\)

\[\log_{16}{{x}^{y}} = y \log_{16}{x}\]

\(\log_{3}{\sqrt{5}}\)

\[\log_{3}{\sqrt{5}} = \frac{\log_{3}{5}}{2}\]

\(\log_{z}{{y}^{z}}\)

\[\log_{z}{{y}^{z}} = z \log_{z}{y}\]

\(\log_{y}{\sqrt[x]{y}}\)

\begin{align*} \log_{y}{\sqrt[x]{y}} &= \log_{y}{y^{\frac{1}{x}}} \\ &= \frac{1}{x} \log_{y}{y} \\ &= \frac{1}{x} \end{align*}

\(\log_{p}{{p}^{q}}\)

\begin{align*} \log_{p}{{p}^{q}} &= q \log_{p}{p} \\ &= q(1) \\ &= q \end{align*}

\(\log_{2}{\sqrt[4]{8}}\)

\begin{align*} \log_{2}{\sqrt[4]{8}} &= \log_{2}{8^{\frac{1}{4}}} \\ &= \frac{1}{4} \log_{2}{2^{3}} \\ &= \frac{1}{4} \times 3 \log_{2}{2} \\ &= \frac{3}{4} \end{align*}

\(\log_{5}{\frac{1}{5}}\)

\begin{align*} \log_{5}{\frac{1}{5}} &= \log_{5}{5^{-1}} \\ &= (-1) \log_{5}{5} \\ &= (-1)(1) \\ &= -1 \end{align*}

\(\log_{2}{{8}^{5}}\)

\begin{align*} \log_{2}{{8}^{5}} &= 5 \log_{2}{{8}} \\ &= 5 \log_{2}{{2}^{3}} \\ &= 5 \times 3 \log_{2}{2} \\ &= 15 \end{align*}

\(\log_{4}{16} \times \log_{3}{81}\)

\begin{align*} \log_{4}{16} \times \log_{3}{81} &= \log_{4}{4^{2}} \times \log_{3}{3^{4}} \\ &= (2) \log_{4}{4} \times (4) \log_{3}{3} \\ &= (2)(1) \times (4)(1)\\ &= 8 \end{align*}

\(\left( \log_{5}{25} \right)^{2}\)

\begin{align*} \left( \log_{5}{25} \right)^{2} &= \left( \log_{5}{5^{2}} \right)^{2} \\ &= \left( 2 \log_{5}{5} \right)^{2} \\ &= \left( 2 (1) \right)^{2} \\ &= 4 \\ \text{Alternative method: } & \\ \left( \log_{5}{25} \right)^{2} &= \log_{5}{ \left( 5^{2} \right)^{2} } \\ &= \log_{5}{5}^{4} \\ &= 4(1) \\ &= 4 \end{align*}

\(\log_{2}{\text{0,125}}\)

\begin{align*} \log_{2}{\text{0,125}} &= \log_{2}{\frac{125}{1000}} \\ &= \log_{2}{\frac{1}{8}} \\ &= \log_{2}{8^{-1}} \\ &= (-1) \log_{2}{2^{3}} \\ &= (-1)(3) \log_{2}{2} \\ &= (-3) (1) \\ &= -3 \end{align*}

Logarithmic law:

\({\log}_{a}x=\frac{{\log}_{b}{x}}{{\log}_{b}{a}} \qquad (b > 0 \text{ and } b \ne 1)\)

It is often necessary or convenient to convert a logarithm from one base to another base. This is referred to as a change of base.

\begin{align*} \text{Let } \quad \log_{a}{x} &= m \\ \therefore x &= a^{m} \\ \text{Consider the fraction: } \quad & \frac{\log_{b}{x}}{\log_{b}{a}} \\ \text{Substitute } x = a^{m}: \quad \frac{\log_{b}{x}}{\log_{b}{a}} &= \frac{\log_{b}{a^{m}}}{\log_{b}{a}} \\ &= m \left( \frac{\log_{b}{a}}{\log_{b}{a}} \right) \\ &= m (1) \\ \therefore \frac{\log_{b}{x}}{\log_{b}{a}}&= \log_{a}{x} \end{align*}

Special applications:

\begin{align*} (1) \qquad \log_{a}{x} &= \frac{\log_{x}{x}}{\log_{x}{a}} \\ \therefore \log_{a}{x} &= \frac{1}{\log_{x}{a}} \\ & \\ & \\ (2) \qquad \log_{a}{\frac{1}{x}} &= \log_{a}{x^{-1}} \\ \therefore \log_{a}{\frac{1}{x}} &= - \log_{a}{x} \end{align*}

Video: 28CT

Worked example 13: Applying the logarithmic law \({\log}_{a}x=\frac{{\log}_{b}{x}}{{\log}_{b}{a}}\)

Show: \(\log_{2}{8} = \frac{\log{8}}{\log{2}}\)

Simplify the right-hand side of the equation

\begin{align*} \text{RHS } &= \frac{\log{8}}{\log{2}} \\ &= \frac{\log{2^{3}}}{\log{2}} \\ &= 3 \left( \frac{\log{2}}{\log{2}} \right) \\ &= 3(1) \\ &= 3 \end{align*}

Simplify the left-hand side of the equation

\begin{align*} \text{LHS } &= \log_{2}{8} \\ &= \log_{2}{2^{3}} \\ &= 3 \log_{2}{2} \\ &= 3(1) \\ &= 3 \end{align*}

Write the final answer

We have shown that \(\log_{2}{8} = \dfrac{\log{8}}{\log{2}} = 3\).

Worked example 14: Applying the logarithmic law \({\log}_{a}x=\frac{{\log}_{b}{x}}{{\log}_{b}{a}}\)

If \(a = \log{2}\) and \(b = \log{3}\), express the following in terms of \(a\) and \(b\):

\(\log_{3}{2}\)
\(\log_{2}{\frac{10}{3}}\)

Use a change of base to simplify the expressions

\begin{align*} \log_{3}{2} &= \frac{\log{2}}{\log{3}} \\ &= \frac{a}{b} \end{align*}
\begin{align*} \log_{2}{\frac{10}{3}} &= \frac{\log{\frac{10}{3}}}{\log{2}} \\ &= \frac{\log{10} - \log{3}}{\log{2}} \\ &= \frac{1- b}{a} \end{align*}

temp text

Applying the logarithmic law: \({\log}_{a}x=\frac{{\log}_{b}{x}}{{\log}_{b}{a}}\)

Textbook Exercise 2.8

\(\log_{2}{4}\) to base \(\text{8}\)

\(\log_{2}{4} = \frac{\log_{8}{4}}{\log_{8}{2}}\)

\(\log_{10}{14}\) to base \(\text{2}\)

\(\log_{10}{14} = \frac{\log_{2}{14}}{\log_{2}{10}}\)

\(\log{4\frac{1}{2}}\) to base \(\text{2}\)

\begin{align*} \log{4\frac{1}{2}} &= \log{\frac{9}{2}} \\ &= \frac{\log_{2}{\frac{9}{2}}}{\log_{2}{10}} \\ &= \frac{\log_{2}{9} - \log_{2}{2}}{\log_{2}{10}} \\ &= \frac{\log_{2}{9} - 1}{\log_{2}{10}} \end{align*}

\(\log_{2}{8}\) to base \(\text{8}\)

\begin{align*} \log_{2}{8} &= \frac{\log_{8}{8}}{\log_{8}{2}} \\ &= \frac{1}{\log_{8}{2}} \end{align*}

\(\log_{y}{x}\) to base \(x\)

\begin{align*} \log_{y}{x} &= \frac{\log_{x}{x}}{\log_{x}{y}} \\ &= \frac{1}{\log_{x}{y}} \end{align*}

\(\therefore\) a logarithm is equal to the reciprocal of its inverse.

\(\)

\(\log_{10}{2x}\) to base \(\text{2}\)

\begin{align*} \log_{10}{2x} &= \frac{\log_{2}{2x}}{\log_{2}{10}} \\ &= \frac{\log_{2}{2} + \log_{2}{x}}{\log_{2}{10}} \\ &= \frac{1 + \log_{2}{x}}{\log_{2}{10}} \end{align*} \(\)

\(\log_{2}{10} \times \log_{10}{2}\)

\begin{align*} \log_{2}{10} \times \log_{10}{2} &= \frac{\log{10}}{\log{2}} \times \frac{\log{2}}{\log{10}} \\ &= 1 \end{align*}

\(\log_{5}{100}\)

\begin{align*} \log_{5}{100} &= \frac{\log{100}}{\log{5}} \\ &= \frac{\log{10^{2}}}{\log{5}} \\ &= \frac{2 \log{10}}{\log{5}} \\ &= \frac{2}{\log{5}} \end{align*}

\(\log_{2}{3}\)

\begin{align*} \log_{2}{3} &= \frac{\log{3}}{\log{2}} \\ &= \frac{\text{0,477}}{\text{0,301}} \\ &= \text{1,58} \end{align*}

\(\log_{3}{2000}\)

\begin{align*} \log_{3}{2000} &= \frac{\log{2000}}{\log{3}} \\ &= \frac{\log{(2 \times 1000)}}{\log{3}} \\ &= \frac{\log{2} + \log{10^{3}}}{\log{3}} \\ &= \frac{\text{0,301} +3(1)}{\text{0,477}} \\ &= \frac{\text{3,301}}{\text{0,477}} \\ &= \text{6,92} \end{align*}

Logarithms using a calculator (EMCFM)

Calculating a logarithmic value

There are many different types and models of scientific calculators. It is very important to be familiar with your own calculator and the different function buttons. Some calculators only have two buttons for logarithms: one for calculating the common logarithm (base is equal to \(\text{10}\)) and another for calculating the natural log (base is equal to \(e\)). Newer models will have a third button which allows the user to calculate the logarithm of a number to a certain base.

Worked example 15: Using a calculator: logarithm function

Use a calculator to determine the following values (correct to \(\text{3}\) decimal places):

\(\log{9}\)
\(\log{\text{0,3}}\)
\(\log{\frac{3}{4}}\)
\(\log{(-2)}\)

Use the common logarithm function on your calculator

Make sure that you are familiar with the “LOG” function on your calculator. Notice that the base for each of the logarithms given above is \(\text{10}\).

Write the final answer

\(\log{9} = \text{0,954}\)
\(\log{\text{0,3}} = -\text{0,523}\)
\(\log{\frac{3}{4}} = -\text{0,125}\)
\(\log{(-2)} =\) undefined

temp text

Worked example 16: Using a calculator: inverse logarithm function

Use a calculator to determine the following values (correct to \(\text{3}\) decimal places):

\(\log{x} = \text{1,7}\)
\(\log{t} = \frac{2}{7}\)
\(\log{y} = -\text{3}\)

Use the second function and common logarithm function on your calculator

For each of the logarithms given above we need to calculate the inverse of the logarithm (sometimes called the antilog). Make sure that you are familiar with the “\(\text{2}\)nd F” button on your calculator.

Notice that by pressing the “\(\text{2}\)nd F” button and then the “LOG” button, we are using the “\(10^{x}\)” function on the calculator, which is correct since exponentials are the inverse of logarithms.

Write the final answer

\(x = \text{50,119}\)
\(t = \text{1,930}\)
\(y = \text{0,001}\)

temp text

Worked example 17: Using a calculator: change of base

Use a calculator to find \(\log_{2}{5}\) correct to two decimal places.

\[\log_{2}{5} = \frac{\log{5}}{\log{2}}\]

Use a change of base to convert given logarithm to base \(\text{10}\)

\[\log_{2}{5} = \frac{\log{5}}{\log{2}}\]

Use the common logarithm function on your calculator

Write the final answer

\[\log_{2}{5} = \text{2,32}\]

Important:

Do not write down an intermediate step when doing this type of calculation:

\begin{align*} \log_{2}{5} &= \frac{\log{5}}{\log{2}} \\ &= \frac{\text{0,7}}{\text{0,3}} \quad (\text{this step can cause rounding off errors}) \\ &= \text{2,33} \end{align*}
Perform the calculation in one step on your calculator:
\begin{align*} \log_{2}{5} &= \frac{\log{5}}{\log{2}} \\ &= \text{2,32} \end{align*}
Do not round off before the final answer as this can affect the accuracy of the answer.
Be sure that you determine the correct sequence and order of operations when using a calculator.

Logarithms using a calculator

Textbook Exercise 2.9

\(\log{3}\)

\(\text{0,477}\)

\(\log{30}\)

\(\text{1,477}\)

\(\log{300}\)

\(\text{2,477}\)

\(\log{0.66}\)

\(-\text{0,180}\)

\(\log{\frac{1}{4}}\)

\(-\text{0,602}\)

\(\log{\text{852}}\)

\(\text{2,930}\)

\(\log{(-6)}\)

no value

\(\log_{3}{4}\)

\(\text{1,262}\)

\(\log{\text{0,01}}\)

\(-\text{2}\)

\(\log_{2}{15}\)

\(\text{3,907}\)

\(\log_{4}{10}\)

\(\text{1,661}\)

\(\log_{\frac{1}{2}}{6}\)

\(-\text{2,585}\)

\(\log{x} = \text{0,6}\)

\begin{align*} x &= \text{3,98}\\ \text{Check exponential form: } 10^{\text{0,6}}&= \text{3,98} \end{align*}

\(\log{x} = -\text{2}\)

\begin{align*} x &= \text{0,01}\\ \text{Check exponential form: } 10^{-\text{2}}&= \text{0,01} \end{align*}

\(\log{x} = \text{1,8}\)

\begin{align*} x &= \text{63,10}\\ \text{Check exponential form: } 10^{\text{1,8}}&= \text{63,10} \end{align*}

\(\log{x} = \text{5}\)

\begin{align*} x &= \text{100 000}\\ \text{Check exponential form: } 10^{\text{5}}&= \text{100 000} \end{align*}

\(\log{x} = -\text{0,5}\)

\begin{align*} x &= \text{0,32}\\ \text{Check exponential form: } 10^{-\text{0,5}}&= \text{0,32} \end{align*}

\(\log{x} = \text{0,076}\)

\begin{align*} x &= \text{1,19}\\ \text{Check exponential form: } 10^{\text{0,076}}&= \text{1,19} \end{align*}

\(\log{x} = \frac{2}{5}\)

\begin{align*} x &= \text{2,51}\\ \text{Check exponential form: } 10^{\frac{2}{5}}&= \text{2,51} \end{align*}

\(\log{x} = -\frac{6}{5}\)

\begin{align*} x &= \text{0,06}\\ \text{Check exponential form: } 10^{\left( -\frac{6}{5} \right)}&= \text{0,06} \end{align*}

\(\log_{2}{x} = \text{0,25}\)

\begin{align*} \log_{2}{x} &= \text{0,25} \\ \therefore \frac{\log{x}}{\log{2}} &= \text{0,25} \\ \therefore \log{x} &= \text{0,25} \times \log{2} \\ \therefore x &= \text{1,19} \\ \text{Check exponential form: } 2^{\text{0,25}}&= \text{1,19} \end{align*}

\(\log_{5}{x} = -\text{0,1}\)

\begin{align*} \log_{5}{x} &= -\text{0,1} \\ \therefore \frac{\log{x}}{\log{5}} &= -\text{0,1} \\ \therefore \log{x} &= -\text{0,1} \times \log{5} \\ \therefore x &= \text{0,85} \\ \text{Check exponential form: } 5^{(-\text{0,10})}&= \text{0,85} \end{align*}

\(\log_{\frac{1}{4}}{x} = \text{2}\)

\begin{align*} \log_{\frac{1}{4}}{x} &= \text{2} \\ \therefore \frac{\log{x}}{\log{\frac{1}{4}}} &= \text{2} \\ \therefore \log{x} &= \text{2} \times \log{\frac{1}{4}} \\ \therefore x &= \text{0,06} \\ \text{Check exponential form: } \left( \frac{1}{4} \right)^{\text{2}}&= \text{0,06} \end{align*}

\(\log_{7}{x} = \text{0,3}\)

\begin{align*} \log_{7}{x} &= \text{0,3} \\ \therefore \frac{\log{x}}{\log{7}} &= \text{0,3} \\ \therefore \log{x} &= \text{0,3} \times \log{7} \\ \therefore x &= \text{1,79} \\ \text{Check exponential form: } 7^{\text{0,3}}&= \text{1,79} \end{align*}

Exponential and logarithmic graphs (EMCFN)

Worked example 18: Graphs of the inverse of \(y=b^{x}\)

On the same system of axes, draw the graphs of \(f(x) = 10^{x}\) and its inverse \(f^{-1}(x) = \log{x}\). Investigate the properties of \(f\) and \(f^{-1}\).

Determine the properties of \(f(x)\)

Function: \(y = 10^{x}\)
Shape: increasing graph
Intercept(s): \((0;1)\)
Asymptote(s): horizontal asymptote at \(x\)-axis, line \(y = 0\)
Domain: \(\{x: x \in \mathbb{R} \}\)
Range: \(\{y: y > 0, y \in \mathbb{R} \}\)

Draw the graphs

The graph of the inverse \(f^{-1}\) is the reflection of \(f\) about the line \(y = x\).

Determine the properties of \(f^{-1}(x)\)

Function: \(y = \log{x}\)
Shape: increasing graph
Intercept(s): \((1;0)\)
Asymptote(s): vertical asymptote at \(y\)-axis, line \(x = 0\)
Domain: \(\{x: x > 0, x \in \mathbb{R} \}\)
Range: \(\{y: y \in \mathbb{R} \}\)

Notice that the inverse is a function: \(f^{-1}(x) = \log{x}\) is a one-to-one function since every input value is associated with only one output value.

The exponential function and the logarithmic function are inverses of each other:

the domain of the function is equal to the range of the inverse
the range of the function is equal to the domain of the inverse
the \(y\)-intercept of the function is equal to the \(x\)-intercept of the inverse
the \(x\)-intercept of the function is equal to the \(y\)-intercept of the inverse
the asymptote for the function is \(y = 0\) and the asymptote for the inverse is \(x = 0\)
the graphs are reflected about the line \(y=x\)

Worked example 19: Graphs of \(y=\log_{b}{x}\)

Draw a sketch of \(g(x) = \log_{10}{x}\).
Reflect the graph of \(g\) about the \(x\)-axis to give the graph \(h\).
Investigate the properties of \(h\).
Use \(g\) and \(h\) to suggest a general conclusion.

Sketch the graph of \(g(x)= \log_{10}{x}\)

Reflect \(g\) about the \(x\)-axis

An easy method for reflecting a graph about a certain line is to imagine folding the Cartesian plane along that line and the reflected graph is pressed onto the plane.

Investigate the properties of \(h\)

Function: passes the vertical line test
Shape: decreasing graph
Intercept(s): \((1;0)\)
Asymptote(s): vertical asymptote at \(y\)-axis, line \(x = 0\)
Domain: \(\{x: x > 0, x \in \mathbb{R} \}\)
Range: \(\{y: y \in \mathbb{R} \}\)

Since \(h(x)\) is symmetrical to \(g(x)\) about the \(x\)-axis, this means that every \(y\)-value of \(g\) corresponds to a \(y\)-value of the opposite sign for \(h\).

\begin{align*} \text{Given } g(x) & = \log_{10}{x} \\ \therefore h(x) & = - \log_{10}{x} \\ \text{Let } y & = - \log_{10}{x} \\ -y & = \log_{10}{x} \\ \therefore 10^{-y} & = x \\ \left( \frac{1}{10} \right)^{y} & = x \\ \therefore y & = \log_{\frac{1}{10}}{x} \\ \therefore h(x) & = - \log_{10}{x} = \log_{\frac{1}{10}}{x} \end{align*}

General conclusion

From this example of \(g\) and \(h\) we see that:

\[-\log_{m}{p} = \log_{\frac{1}{m}}{p}\]

Worked example 20: Graph of \(y=\log_{b}{x}\)

Draw a sketch of \(h(x) = \log_{\frac{1}{10}}{x}\).
Draw the graph of \(r(x)\), the reflection of \(h\) about the line \(y = x\).
Investigate the properties of \(r\).
Write down the new equation if \(h\) is shifted \(\text{1}\) unit upwards and \(\text{2}\) units to the right.

Sketch the graph of \(h(x)= \log_{\frac{1}{10}}{x}\)

Reflect \(h\) about the line \(y = x\)

Investigate the properties of \(r\)

Function: passes the vertical line test
Shape: decreasing graph
Intercept(s): \((0;1)\)
Asymptote(s): horizontal asymptote at \(x\)-axis, line \(y = 0\)
Domain: \(\{x: x \in \mathbb{R} \}\)
Range: \(\{y: y > 0, y \in \mathbb{R} \}\)

Since \(h(x)\) is symmetrical to \(r(x)\) about the line \(y = x\), this means that \(r\) is the inverse of \(h\).

\begin{align*} h(x) & = \log_{\frac{1}{10}}{x} \\ \text{Let } y & = \log_{\frac{1}{10}}{x} \\ \text{Inverse: } x & = \log_{\frac{1}{10}}{y} \\ \therefore \left( \frac{1}{10} \right)^{x} & = y \\ {10}^{-x} & = y \\ & \\ \therefore r(x) = h^{-1}(x)& = {10}^{-x} \end{align*}

Therefore, \(r(x)\) is an exponential function of the form \(y = b^{x}\) with \(0 < b < 1\). In words, the base \(b\) is a positive fraction with a value between \(\text{0}\) and \(\text{1}\).

Vertical and horizontal shifts

If \(h\) is shifted \(\text{1}\) unit upwards and \(\text{2}\) units to the right, then the new equation will be: \[y = \log_{\frac{1}{10}}{(x - 2)} + 1\]

The vertical asymptote is \(x = 2\) and the horizontal asymptote is \(y = 1\).

Summary of graphs: \(y = b^{x}\) and \(y = \log_{b}{x}\)

	Exponential function	Logarithmic function	Axis of symmetry
	\(y = b^{x}\)	\(y = \log_{b}{x}\)	\(y = x\)
\(b > 1\)
\(0 < b < 1\)
Axis of symmetry	\(y\)-axis, \(x = 0\)	\(x\)-axis, \(y = 0\)

Video: 28F3

Graphs and inverses of \(y=\log_{b}{x}\)

Textbook Exercise 2.10

Sketch the graphs of \(f\) and \({f}^{-1}\) on the same system of axes. Label both graphs clearly.

State the intercept(s) for each graph.

\(f: (0;1)\) and \(f^{-1}: (1;0)\)

Label \(P\), the point of intersection of \(f\) and \(f^{-1}\).

Notice that the function and its inverse intersect at a point that lies on the line \(y = x\).

State the domain, range and asymptote(s) of each function.

Function	Domain	Range	Asymptote
\(f(x) = \left( \frac{1}{5} \right)^{x}\)	\(\{x: x \in \mathbb{R} \}\)	\(\{y: y > 0, y \in \mathbb{R} \}\)	\(x\)-axis, \(y=0\)
\(f^{-1}(x) = \log_{\frac{1}{5}}{x}\)	\(\{x: x > 0, x \in \mathbb{R} \}\)	\(\{y: y \in \mathbb{R} \}\)	\(y\)-axis, \(x=0\)

Determine the value of \(t\)

\begin{align*} \text{Let } y &= t^{x} \\ \text{5,8} &= t^{\text{1,6}} \\ \therefore t &= \sqrt[\text{1,6}]{\text{5,8}} \\ &= \text{3,000} \ldots \\ & \\ \therefore g(x) &= 3^{x} \end{align*}

Find the inverse of \(g\).

\begin{align*} \text{Let } y & = 3^{x} \qquad (y > 0) \\ \text{Interchange } x \text{ and } y: \quad x & = 3^{y} \qquad (x > 0) \\ \frac{x}{2} & = y^{2} \\ y & = \log_{3}{x} \\ & \\ \therefore g^{-1}(x) & = \log_{3}{x} \qquad (x > 0) \end{align*}

Use symmetry about the line \(y = x\) to sketch the graphs of \(g\) and \({g}^{-1}\) on the same system of axes.

Point \(N\) lies on the graph of \(g^{-1}\) and is symmetrical to point \(M\) about the line \(y = x\). Determine the coordinates of \(N\).

\(N( \text{5,8}; \text{1,6})\)

Applications of logarithms (EMCFP)

Logarithms have many different applications:

seismologists use logarithms to calculate the magnitude of earthquakes
financial institutions make use of logarithms to calculate the length of loan repayments
scientists use logarithms to determine the rate of radioactive decay
biologists use logarithms to calculate population growth rates
scientists use logarithms to determine pH levels \[\text{pH} = - \log_{10}{[H^{+}]}\]

Video: 28F6

Worked example 21: Population growth

The population of a city grows by \(\text{5}\%\) every two years. How long will it take for the city's population to triple in size?

Write down a suitable formula and the known values

\[A=P{\left(1+i\right)}^{n}\]

Let \(P = x\)
The population triples in size, so \(A = 3x\)
Growth rate \(i = \frac{5}{100}\)
Growth rate is given for a \(\text{2}\) year period, so we use \(\frac{n}{2}\)

Substitute known values and solve for \(n\)

\begin{align*} 3x &=x{\left(1+\frac{5}{100}\right)}^{\frac{n}{2}} \\ 3 & = {\left(1,05\right)}^{\frac{n}{2}} \end{align*}

Method \(\text{1}\): take the logarithm of both sides of the equation

\begin{align*} \log{3}& = \log{\left(1,05\right)}^{\frac{n}{2}} \\ \log{3}& = \frac{n}{2}\times \log{1,05} \\ 2 \times \frac{\log3}{\log{1,05}} & = n \\ 45,034 \ldots & = n \end{align*}

Method \(\text{2}\): change from exponential form to logarithmic form

\begin{align*} \frac{n}{2} & = \log_{\text{1,05}}{3} \\ & = \frac{\log{3}}{\log{\text{1,05}}} \\ n & = 2 \times \frac{\log3}{\log{1,05}} \\ n & = 45,034 \ldots \end{align*}

Write the final answer

It will take approximately \(\text{45}\) years for the city's population to triple in size.

Applications of logarithms

Textbook Exercise 2.11

The population of Upington grows \(\text{6}\%\) every \(\text{3}\) years. How long will it take to triple in size?

Give your answer in years and round to the nearest integer.

This is a compound growth problem. You should first write down the initial size of the population, the final size of the population and the rate at which the population grows. Note that every period is \(\text{3}\) years long.

Let the population at the start be \[P = x\] We want to know how many periods it will take to triple in size. This means that the final population is \[A = 3x\]

Let \(n\) be the number of periods needed to grow to a size of \(A\). Note that every period is \(\text{3}\) years long, therefore we must use \(\frac{n}{\text{3}}\).

The growth rate is \[i = \text{6}\% = \frac{\text{6}}{\text{100}}\]

We use the formula for compound growth/interest: \begin{align*} A &= P(1+i)^n \\ 3x &= x\left(1 + \frac{\text{6}}{\text{100}}\right)^{\frac{n}{\text{3}}} \\ \text{3} &= (\text{1,06})^{\frac{n}{\text{3}}} \end{align*}

We now use the definition of the logarithm to write the equation in terms of \(n\) and then evaluate with a calculator: \begin{align*} \frac{n}{\text{3}} &= \log_{(\text{1,06})} \text{3} \\ &= \frac{\log{3}}{\log{\text{1,06}}} \\ &= \text{18,854}\ldots \\ \therefore n &= 3 \times \text{18,854}\ldots \\ &= \text{56,562}\ldots \\ &\approx \text{57} \end{align*}

It will take approximately \(\text{57}\) years for the population to triple in size.

Determine a formula that describes the growth of the population.

Let the number of months be \(M_{0}; M_{1}; M_{2}; \ldots\)

\(M_{0}\)	\(\)	\(M_{1}\)	\(\)	\(M_{2}\)	\(\)	\(\ldots\)
\(\text{36}\)	\(\rightarrow\)	\(\text{72}\)	\(\rightarrow\)	\(\text{144}\)	\(\rightarrow\)	\(\ldots\)
	\(\times 2\)		\(\times 2\)		\(\times 2\)

\(36 \times 2^{0} \quad \rightarrow \quad 36 \times 2^{1} \quad \rightarrow \quad 36 \times 2^{2} \quad \rightarrow \quad \ldots\)

\[\text{Growth } = 36 \times 2^{n}\]

where \(n\) is the number of months.

Calculate how long it will take for the ant population to reach a quarter of a million ants.

\begin{align*} \text{Growth } &= 36 \times 2^{n} \\ \frac{1}{4} \times \text{1 000 000} &= 36 \times 2^{n} \\ \text{250 000} &= 36 \times 2^{n} \\ \frac{\text{250 000}}{36} &= 2^{n} \\ \therefore n &= \log_{2}{ \left( \frac{\text{250 000}}{36} \right) } \\ n &= \frac{\log{\left( \frac{\text{250 000}}{36} \right)}}{\log{2}} \\ \therefore n &= \frac{\log{\left( \frac{\text{250 000}}{36} \right)}}{\log{2}} \\ &= \text{12,7} \ldots \end{align*}

There will be a quarter of a million ants after about \(\text{13}\) months.

2.5 Quadratic functions

Table of Contents

2.7 Summary