7. Inverse Functions and Logarithms

7.02 Radical functions

7.03 Solving radical equations

7.04 Exponential functions and the natural base e

7.05 Logarithmic functions

7.06 Properties of logarithms

7.07 Exponential and logarithmic equations

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United States of America

Grades 9-12

7.07 Exponential and logarithmic equations

Lesson

Practice

Introduction

We were introduced to the properties of logarithms in the previous lesson. These properties simplify logarithmic expressions and equations, making it easier to find the solutions to equations. This lesson explores different strategies for solving exponential and logarithmic equations using logarithms and their properties.

Solving exponential equations

Certain exponential equations arise that can be easily solved without resorting to logarithms. The key to their solution lies in the recognition of various powers of integers. We can solve these types of equations by rewriting both sides of the equation with the same base to some power. If we can do this, we can use the equality property of exponents which says b^x=b^y \iff x=y If both sides of the equation cannot be written in the same base, another method of solving exponential equations is taking the logarithm of both sides. Then, we can use properties of logarithms to solve the equation. Often, we will evaluate the solutions to these equations with a calculator.

If these methods do not work, we can use technology to estimate solutions. To solve with a graphing calculator, we can graph the expression on the left side of the equation, graph the expression on the right side of the equation, and then find their point of intersection.

Examples

Example 1

Solve each equation for x.

2^{1-2x}=\dfrac{1}{512}

Worked Solution

Create a strategy

The denominator of the right side of the equation, 512, is a power of 2. By first rewriting this as a power with a base of 2, we can simplify the process needed to solve this equation.

Apply the idea

\displaystyle 2^{1-2x}	\displaystyle =	\displaystyle \frac{1}{512}	State the equation
\displaystyle 2^{1-2x}	\displaystyle =	\displaystyle \frac{1}{2^{9}}	Rewrite 512 as a power of 2
\displaystyle 2^{1-2x}	\displaystyle =	\displaystyle 2^{-9}	Negative exponent property
\displaystyle 1-2x	\displaystyle =	\displaystyle -9	Equality property of exponents
\displaystyle -2x	\displaystyle =	\displaystyle -10	Subtraction property of equality
\displaystyle x	\displaystyle =	\displaystyle 5	Division property of equality

Reflect and check

In general, a fraction in an exponential equation will typically lead to a negative exponent.

e^{2x+3}=4

Worked Solution

Create a strategy

We cannot rewrite 4 as e to some power, so we cannot use that method to solve this equation. The inverse of e^x is \ln\left(x\right), so we can use the equality property of logarithms to take the natural logarithm of both sides. Then, use the inverse property of logarithms to simplify.

Apply the idea

\displaystyle e^{2x+3}	\displaystyle =	\displaystyle 4	Original equation
\displaystyle \ln(e^{2x+3})	\displaystyle =	\displaystyle \ln(4)	Equality property of logarithms
\displaystyle 2x+3	\displaystyle =	\displaystyle \ln(4)	Inverse property of natural logarithms
\displaystyle 2x	\displaystyle =	\displaystyle \ln(4)-3	Subtraction property of equality
\displaystyle x	\displaystyle =	\displaystyle \frac{\ln(4)-3}{2}	Division property of equality

The exact answer is x=\dfrac{\ln\left(4\right)-3}{2}.

Reflect and check

We can find an approximate solution using technology, x\approx -0.8069.

2^{3x-1}=5^{x}

Worked Solution

Create a strategy

We cannot rewrite 2 and 5 as powers with the same base, and taking the logarithm of both sides would be complicated. Estimating the solution using technology is the simplest method for solving this equation.

Apply the idea

First, we need to graph y=2^{3x-1} and y=5^x on the same plane.

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Then, we need to adjust the window to view the intersection of the lines. The lines appear to intersect between x=1 and x=2 and between y=9 and y=12.

We can use the intersect feature of a graphing calculator to find that the lines intersect at x\approx 1.475.

Reflect and check

Solving this equation by taking the logarithm of both sides is complicated but possible.

\displaystyle 2^{3x-1}	\displaystyle =	\displaystyle 5^x	Original equation
\displaystyle \log 2^{3x-1}	\displaystyle =	\displaystyle \log 5^x	Equality property of logarithms
\displaystyle \left(3x-1\right)\log 2	\displaystyle =	\displaystyle x\log 5	Power property of logarithms
\displaystyle 3x\log 2-\log 2	\displaystyle =	\displaystyle x\log 5	Distributive property
\displaystyle 3x\log 2-\log 2-x\log 5	\displaystyle =	\displaystyle 0	Subtraction property of equality
\displaystyle 3x\log 2-x\log 5	\displaystyle =	\displaystyle \log 2	Addition property of equality
\displaystyle x\left(3\log 2-\log 5\right)	\displaystyle =	\displaystyle \log 2	Distributive property
\displaystyle x	\displaystyle =	\displaystyle \frac{\log 2}{3\log 2-\log 5}	Division property of equality

If we used a calculator to approximate the decimal, we would find x\approx1.475.

Example 2

A video posted online initially had 4 views as soon as it was posted. The total number of views to date has been increasing by approximately 12\% each day. Determine when the video will reach 1 million views.

Worked Solution

Create a strategy

We can write an exponential equation to model this situation. The exponential form of an equation is f\left(x\right)=ab^x where a is the initial value, b is the growth factor, x is the number of days, and f\left(x\right) is the number of views.

The number of views increases by 12\%, so the growth factor is 1+0.12=1.12.

Apply the idea

The equation that models the number of views is f\left(x\right)=4\left(1.12\right)^x.

We can solve for when the video reaches 1 million views by setting f\left(x\right) equal to 1\,000\,000.

\displaystyle 4\left(1.12\right)^x	\displaystyle =	\displaystyle 1\,000\,000	Set f\left(x\right) equal to 1 million views
\displaystyle \left(1.12\right)^x	\displaystyle =	\displaystyle 250\,000	Division property of equality
\displaystyle x	\displaystyle =	\displaystyle \log_{1.12}\left(250\,000\right)	Rewrite as a logarithmic equation
\displaystyle x	\displaystyle =	\displaystyle \frac{\log{\left(250\,000\right)}}{\log\left(1.12\right)}	Change of base property
\displaystyle x	\displaystyle \approx	\displaystyle 109.67405	Evaluate using technology

Assuming the views continue to increase by 12\% per day, the video will reach 1 million views in 110 days.

Reflect and check

Another way to solve this is by using the equality property of logarithms after the second step:

\displaystyle 4\left(1.12\right)^x	\displaystyle =	\displaystyle 1\,000\,000	Set f\left(x\right) equal to 1 million views
\displaystyle \left(1.12\right)^x	\displaystyle =	\displaystyle 250\,000	Division property of equality
\displaystyle \log\left(1.12\right)^x	\displaystyle =	\displaystyle \log\left(250\,000\right)	Equality property of logarithms
\displaystyle x\log\left(1.12\right)	\displaystyle =	\displaystyle \log\left(250\,000\right)	Power property of logarithms
\displaystyle x	\displaystyle =	\displaystyle \frac{\log\left(250\,000\right)}{\log\left(1.12\right)}	Division property of equality
\displaystyle x	\displaystyle \approx	\displaystyle 109.67405	Evaluate using technology

Idea summary

There are three main strategies for solving exponential equations:

Rewrite both sides of the equation with the same base to some power
Rewrite in logarithmic form or use the equality property to introduce logarithms on either side
If neither of the above strategies works, estimate the solution(s) using technology

Solving logarithmic equations

Many logarithmic equations can be solved by rewriting it in exponential form. The properties of logarithms may need to be used to condense the equation down to one logarithm before switching it to exponential form.

Recall a logarithmic function of the form \log_b\left(x\right) has domain x>0. When solving logarithmic equations, we need to ensure our answers make sense in context and that we are never taking the logarithm of a negative number. We may find that, for some logarithmic equations, a solution resulting from the process of solving is extraneous because it results in a negative argument.

Logarithmic equations which have non-zero expressions on both sides can be solved graphically. To do this, set the expressions on both sides equal to y, graph each equation on the same coordinate plane, then find the point(s) of intersection.

Examples

Example 3

Solve each equation, indicating whether each solution is viable or extraneous.

\dfrac{1}{3}\log_{5} x +7=8

Worked Solution

Create a strategy

The first thing we want to do is isolate the logarithm. Then, we can rewrite it in exponential form and solve for x. The domain of the logarithm is x>0.

Apply the idea

\displaystyle \frac{1}{3}\log_{5} x +7	\displaystyle =	\displaystyle 8	Original equation
\displaystyle \frac{1}{3}\log_{5} x	\displaystyle =	\displaystyle 1	Subtraction property of equality
\displaystyle \log_{5} x	\displaystyle =	\displaystyle 3	Multiplication property of equality
\displaystyle x	\displaystyle =	\displaystyle 5^3	Definition of logarithm
\displaystyle x	\displaystyle =	\displaystyle 125	Evaluate the exponent

The result lies within the domain, so the solution x=125 is valid.

Reflect and check

When we get to the step \log_5 x =3, we can use the equality property of exponents instead of switching it to exponential form.

\displaystyle \log_5 x	\displaystyle =	\displaystyle 3
\displaystyle 5^{\log_5 x}	\displaystyle =	\displaystyle 5^3
\displaystyle x	\displaystyle =	\displaystyle 5^3
\displaystyle x	\displaystyle =	\displaystyle 125

This method is helpful when solving logarithmic inequalities.

\log_6 \left(x\right)+\log_6 \left(x+9\right)=2

Worked Solution

Create a strategy

We can rewrite the left hand side using the product property of logarithms: \log_b\left(x\right)+ \log_b\left(y\right) =\log_b\left(xy\right) We can then use the identity \log_b x=n \iff x=b^n , to rewrite the expression without logarithms.

Apply the idea

\displaystyle \log_6 x+\log_6 \left(x+9\right)	\displaystyle =	\displaystyle 2	State the equation
\displaystyle \log_6 \left[x\left(x+9\right)\right]	\displaystyle =	\displaystyle 2	Product property of logarithms
\displaystyle \log_6\left(x^2+9x\right)	\displaystyle =	\displaystyle 2	Distributive property
\displaystyle x^2+9x	\displaystyle =	\displaystyle 6^2	Definition of logarithm
\displaystyle x^2+9x	\displaystyle =	\displaystyle 36	Evaluate the square
\displaystyle x^2+9x-36	\displaystyle =	\displaystyle 0	Subtraction property of equality
\displaystyle \left(x-3\right)\left(x+12\right)	\displaystyle =	\displaystyle 0	Factor the quadratic

This gives us two possible solutions x=3 and x=-12.

To test for extraneous solutions, we want to check if any solution falls outside the domain of the logarithms. The logarithms in the original equation are \log_6 x and \log_6 \left(x+9\right), and we cannot take the logarithm of a negative value.

According to the first term, x must be greater than 0. According to the second term, x must be greater than -9. However, any number between -9 and 0 will make the first term undefined, so the domain for this equation is \left(0, \infty\right).

We now need to check if either solution is extraneous. As -12 < 0, it falls outside the domain of the function and is therefore extraneous.

x=3 is a valid solution.

Reflect and check

We can check our solution by substituting x=3 into the equation:

\displaystyle \log_6\left(3\right)+\log_6\left(3+9\right)	\displaystyle =	\displaystyle \log_6\left(3\cdot 12\right)
	\displaystyle =	\displaystyle \log_6\left(36\right)
	\displaystyle =	\displaystyle \log_6\left(6^2\right)
	\displaystyle =	\displaystyle 2

Substituting x=3 makes the equation true, so we confirm that it is a valid solution.

\log _n\left(x+4\right)-\log _n\left(x-2\right)=\log _n\left(x\right)

Worked Solution

Create a strategy

We can rewrite the left hand side using the quotient property of logarithms: \log_b\left(x\right)- \log_b\left(y\right) =\log_b\left(\frac{x}{y}\right) This will give us an equation of the form \log_b\left(x\right)=\log_b\left(y\right) which we can simplify using the equality property\log_b\left(x\right)=\log_b\left(y\right) \iff x=y

Apply the idea

\displaystyle \log _n\left(x+4\right)-\log _n\left(x-2\right)	\displaystyle =	\displaystyle \log _n\left(x\right)	State the equation
\displaystyle \log _n\left(\frac{x+4}{x-2}\right)	\displaystyle =	\displaystyle \log _n\left(x\right)	Quotient property of logarithms
\displaystyle \frac{x+4}{x-2}	\displaystyle =	\displaystyle x	Equality property of logarithms
\displaystyle x+4	\displaystyle =	\displaystyle x\left(x-2\right)	Multiplication property of equality
\displaystyle x+4	\displaystyle =	\displaystyle x^2-2x	Distributive property
\displaystyle 0	\displaystyle =	\displaystyle x^2-3x-4	Subtraction property of equality
\displaystyle 0	\displaystyle =	\displaystyle \left(x+1\right)\left(x-4\right)	Factor the quadratic

This gives us two possible solutions x=-1 and x=4.

To test for extraneous solutions, we want to check if any solution falls outside the domain of the logarithms. The logarithmic terms in the original equation are \log_n\left(x+4\right), \log_n\left(x-2\right), and \log_n\left(x\right).

Logarithm	Domain
\log_n \left(x+4\right)	\left(-4,\infty\right)
\log_n \left(x-2\right)	\left(2,\infty\right)
\log_n x	\left(0,\infty\right)

Any number between -4 and 2 will make the second term undefined, so the domain for this equation is \left(2, \infty\right).

We now need to check if either solution is extraneous. As -1 <2, it falls outside the domain of the function and is therefore extraneous.

x=4 is a valid solution.

Reflect and check

We can check our solution by substituting x=4 into the equation:

\displaystyle \log_n\left(x+4\right)-\log_n\left(x-2\right)	\displaystyle =	\displaystyle \log_n\left(x\right)
\displaystyle \log_n\left(4+4\right)-\log_n\left(4-2\right)	\displaystyle =	\displaystyle \log_n\left(4\right)
\displaystyle \log_n\left(8\right)-\log_n\left(2\right)	\displaystyle =	\displaystyle \log_n\left(4\right)
\displaystyle \log_n\left(\frac{8}{2}\right)	\displaystyle =	\displaystyle \log_n\left(4\right)
\displaystyle \log_n\left(4\right)	\displaystyle =	\displaystyle \log_n\left(4\right)

Example 4

Consider the equation 7\log_{10}\left(x+3\right)=x+2.

Sketch the graph of y=7\log_{10}\left(x+3\right).

Worked Solution

Create a strategy

We can graph this equation by first completing a table of values and drawing the curve that passes through these points, or we can consider how the function f\left(x\right)=\log_{10}\left(x\right) has been transformed.

Considering each component separately, we can see that the graph of y=\log_{10}\left(x\right) is stretched vertically by a factor of 7 and translated 3 units to the left.

Apply the idea

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First, the graph of y=\log_{10}\left(x\right) is stretched vertically by a factor of 7 .
This corresponds with the graph of {y=7\log_{10}\left(x\right)}.

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Next, the graph of f\left(x\right)=7\log_{10}\left(x\right) is translated 3 units to the left.
This corresponds with the graph of {y=7\log_{10}\left(x+3\right)}.

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Reflect and check

Remember that we apply stretches, compressions, and reflections before applying translations.

Graph y=x+2 on the same coordinate plane.

Worked Solution

Create a strategy

The graph of y=x+2 is a straight line with a slope of 1 and a y-intercept of 2.

Apply the idea

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Estimate the solutions to the equation, rounding to the nearest integer.

Worked Solution

Create a strategy

The solutions to the equation will be the points where the two graphs intersect.

Apply the idea

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Rounding to the nearest integer, we get the solutions x=-2 and x=4.

Reflect and check

We can confirm that x=-2 is exactly a solution algebraically, as the left hand side of the equation becomes 7\log_{10}\left(1\right)= 0, and the right hand side becomes -2+2=0, as expected. We cannot do the same for x=4, which tells us that this solution must have been rounded.

Idea summary

To solve logarithmic equations, we can use properties of logarithms to condense the terms and then use the definition of logarithms to switch to exponential form. If this is not possible or practical, we can estimate the solution(s) using technology.

Outcomes

A.CED.A.1

Create equations and inequalities in one variable and use them to solve problems.

A.REI.D.11

Explain why the x-coordinates of the points where the graphs of the equations y = f(x) and y = g(x) intersect are the solutions of the equation f(x) = g(x); find the solutions approximately.

F.LE.A.4

For exponential models, express as a logarithm the solution to ab^(ct) = d where a, c, and d are numbers and the base b is 2, 10, or e; evaluate the logarithm using technology.

7.07 Exponential and logarithmic equations

Introduction

Ideas

Solving exponential equations

Examples

Example 1

Example 2

Solving logarithmic equations

Examples

Example 3

Example 4

Outcomes

A.CED.A.1

A.REI.D.11

F.LE.A.4

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