Chapter 10 Review Exercises

Exercise \(\PageIndex{1}\) Find and Evaluate Composite Functions

In the following exercises, for each pair of functions, find

1. \((f \circ g)(x)\)
2. \((g \circ f)(x)\)
3. \((f \cdot g)(x)\)

1. \(f(x)=7 x-2\) and \(g(x)=5 x+1\)

2. \(f(x)=4 x\) and \(g(x)=x^{2}+3 x\)

Answer

2.

1. \(4 x^{2}+12 x\)
2. \(16 x^{2}+12 x\)
3. \(4 x^{3}+12 x^{2}\)

Exercise \(\PageIndex{2}\) Find and Evaluate Composite Functions

In the following exercises, evaluate the composition.

1. For functions \(f(x)=3 x^{2}+2\) and \(g(x)=4 x-3\), find
   1. \((f \circ g)(-3)\)
   2. \((g \circ f)(-2)\)
   3. \((f \circ f)(-1)\)
2. For functions \(f(x)=2 x^{3}+5\) and \(g(x)=3 x^{2}-7\), find
   1. \((f \circ g)(-1)\)
   2. \((g \circ f)(-2)\)
   3. \((g \circ g)(1)\)

Answer

2.

1. \(-123\)
2. \(356\)
3. \(41\)

Exercise \(\PageIndex{3}\) Determine Whether a Function is One-to-One

In the following exercises, for each set of ordered pairs, determine if it represents a function and if so, is the function one-to-one.

1. \(\begin{array}{l}{\{(-3,-5),(-2,-4),(-1,-3),(0,-2)} , {(-1,-1),(-2,0),(-3,1) \}}\end{array}\)
2. \(\begin{array}{l}{\{(-3,0),(-2,-2),(-1,0),(0,1)} , {(1,2),(2,1),(3,-1) \}}\end{array}\)
3. \(\begin{array}{l}{\{(-3,3),(-2,1),(-1,-1),(0,-3)} , {(1,-5),(2,-4),(3,-2) \}}\end{array}\)

Answer

2. Function; not one-to-one

Exercise \(\PageIndex{4}\) Determine Whether a Function is One-to-One

In the following exercises, determine whether each graph is the graph of a function and if so, is it one-to-one.

1. 1. 
      
      Figure 10.E.1
   2. 
      
      Figure 10.E.2
2. 1. 
      
      Figure 10.E.3
   2. 
      
      Figure 10.E.4

Answer

1.

1. Function; not one-to-one
2. Not a function

Exercise \(\PageIndex{5}\) Find the Inverse of a Function

In the following exercise, find the inverse of the function. Determine the domain and range of the inverse function.

1. \(\{(-3,10),(-2,5),(-1,2),(0,1)\}\)

Answer

1. Inverse function: \(\{(10,-3),(5,-2),(2,-1),(1,0)\}\). Domain: \(\{1,2,5,10\}\). Range: \(\{-3,-2,-1,0\}\).

Exercise \(\PageIndex{6}\) Find the Inverse of a Function

In the following exercise, graph the inverse of the one-to-one function shown.

Answer

Solve on your own

Exercise \(\PageIndex{7}\) Find the Inverse of a Function

In the following exercises, verify that the functions are inverse functions.

1. \(\begin{array}{l}{f(x)=3 x+7 \text { and }} {g(x)=\frac{x-7}{3}}\end{array}\)
2. \(\begin{array}{l}{f(x)=2 x+9 \text { and }} {g(x)=\frac{x+9}{2}}\end{array}\)

Answer

1. \(g(f(x))=x,\) and \(f(g(x))=x,\) so they are inverses.

Exercise \(\PageIndex{8}\) Find the Inverse of a Function

1. \(f(x)=6 x-11\)
2. \(f(x)=x^{3}+13\)
3. \(f(x)=\frac{1}{x+5}\)
4. \(f(x)=\sqrt[5]{x-1}\)

Answer

1. \(f^{-1}(x)=\frac{x+11}{6}\)

3. \(f^{-1}(x)=\frac{1}{x}-5\)

Exercise \(\PageIndex{9}\) Graph Exponential Functions

In the following exercises, graph each of the following functions.

1. \(f(x)=4^{x}\)
2. \(f(x)=\left(\frac{1}{5}\right)^{x}\)
3. \(g(x)=(0.75)^{x}\)
4. \(g(x)=3^{x+2}\)
5. \(f(x)=(2.3)^{x}-3\)
6. \(f(x)=e^{x}+5\)
7. \(f(x)=-e^{x}\)

Answer

1.

3.

5.

7.

Exercise \(\PageIndex{10}\) Solve Exponential Equations

In the following exercises, solve each equation.

1. \(3^{5 x-6}=81\)
2. \(2^{x^{2}}=16\)
3. \(9^{x}=27\)
4. \(5^{x^{2}+2 x}=\frac{1}{5}\)
5. \(e^{4 x} \cdot e^{7}=e^{19}\)
6. \(\frac{e^{x^{2}}}{e^{15}}=e^{2 x}\)

Answer

2. \(x=-2, x=2\)

4. \(x=-1\)

6. \(x=-3, x=5\)

Exercise \(\PageIndex{11}\) Use Exponential Models in Applications

In the following exercises, solve.

1. Felix invested $\(12,000\) in a savings account. If the interest rate is \(4\)% how much will be in the account in \(12\) years by each method of compounding?
   1. compound quarterly
   2. compound monthly
   3. compound continuously
2. Sayed deposits $\(20,000\) in an investment account. What will be the value of his investment in \(30\) years if the investment is earning \(7\)% per year and is compounded continuously?
3. A researcher at the Center for Disease Control and Prevention is studying the growth of a bacteria. She starts her experiment with \(150\) of the bacteria that grows at a rate of \(15\)% per hour. She will check on the bacteria every \(24\) hours. How many bacteria will he find in \(24\) hours?
4. In the last five years the population of the United States has grown at a rate of \(0.7\)% per year to about \(318,900,000\). If this rate continues, what will be the population in \(5\) more years?

Answer

2. \(\$ 163,323.40\)

4. \(330,259,000\)

Exercise \(\PageIndex{12}\) Convert Between Exponential and Logarithmic Form

In the following exercises, convert from exponential to logarithmic form.

1. \(5^{4}=625\)
2. \(10^{-3}=\frac{1}{1,000}\)
3. \(63^{\frac{1}{5}}=\sqrt[5]{63}\)
4. \(e^{y}=16\)

Answer

2. \(\log \frac{1}{1,000}=-3\)

4. \(\ln 16=y\)

Exercise \(\PageIndex{13}\) Convert Between Exponential and Logarithmic Form

In the following exercises, convert each logarithmic equation to exponential form.

1. \(7=\log _{2} 128\)
2. \(5=\log 100,000\)
3. \(4=\ln x\)

Answer

2. \(100000=10^{5}\)

Exercise \(\PageIndex{14}\) Evaluate Logarithmic Functions

In the following exercises, solve for \(x\).

1. \(\log _{x} 125=3\)
2. \(\log _{7} x=-2\)
3. \(\log _{\frac{1}{2}} \frac{1}{16}=x\)

Answer

1. \(x=5\)

3. \(x=4\)

Exercise \(\PageIndex{15}\) Evaluate Logarithmic Functions

In the following exercises, find the exact value of each logarithm without using a calculator.

1. \(\log _{2} 32\)
2. \(\log _{8} 1\)
3. \(\log _{3} \frac{1}{9}\)

Answer

2. \(0\)

Exercise \(\PageIndex{16}\) Graph Logarithmic Functions

In the following exercises, graph each logarithmic function.

1. \(y=\log _{5} x\)
2. \(y=\log _{\frac{1}{4}} x\)
3. \(y=\log _{0.8} x\)

Answer

1.

3.

Exercise \(\PageIndex{17}\) Solve Logarithmic Equations

In the following exercises, solve each logarithmic equation.

1. \(\log _{a} 36=5\)
2. \(\ln x=-3\)
3. \(\log _{2}(5 x-7)=3\)
4. \(\ln e^{3 x}=24\)
5. \(\log \left(x^{2}-21\right)=2\)

Answer

2. \(x=e^{-3}\)

4. \(x=8\)

Exercise \(\PageIndex{18}\) Use Logarithmic Models in Applications

What is the decibel level of a train whistle with intensity \(10^{−3}\) watts per square inch?

Answer

\(90\) dB

Exercise \(\PageIndex{19}\) Use the Properties of Logarithms

In the following exercises, use the properties of logarithms to evaluate.

1. 1. \(\log _{7} 1\)
   2. \(\log _{12} 12\)
2. 1. \(5^{\log _{5} 13}\)
   2. \(\log _{3} 3^{-9}\)
3. 1. \(10^{\log \sqrt{5}}\)
   2. \(\log 10^{-3}\)
4. 1. \(e^{\ln 8}\)
   2. \(\ln e^{5}\)

Answer

2.

1. \(13\)
2. \(-9\)

4.

1. \(8\)
2. \(5\)

Exercise \(\PageIndex{20}\) Use the Properties of Logarithms

In the following exercises, use the Product Property of Logarithms to write each logarithm as a sum of logarithms. Simplify if possible.

1. \(\log _{4}(64 x y)\)
2. \(\log 10,000 m\)

Answer

2. \(4+\log m\)

Exercise \(\PageIndex{21}\) Use the Properties of Logarithms

In the following exercises, use the Quotient Property of Logarithms to write each logarithm as a sum of logarithms. Simplify, if possible.

1. \(\log _{7} \frac{49}{y}\)
2. \(\ln \frac{e^{5}}{2}\)

Answer

2. \(5-\ln 2\)

Exercise \(\PageIndex{22}\) Use the Properties of Logarithms

In the following exercises, use the Power Property of Logarithms to expand each logarithm. Simplify, if possible.

1. \(\log x^{-9}\)
2. \(\log _{4} \sqrt[7]{z}\)

Answer

2. \(\frac{1}{7} \log _{4} z\)

Exercise \(\PageIndex{23}\) Use the Properties of Logarithms

In the following exercises, use properties of logarithms to write each logarithm as a sum of logarithms. Simplify if possible.

1. \(\log _{3}\left(\sqrt{4} x^{7} y^{8}\right)\)
2. \(\log _{5} \frac{8 a^{2} b^{6} c}{d^{3}}\)
3. \(\ln \frac{\sqrt{3 x^{2}-y^{2}}}{z^{4}}\)
4. \(\log _{6} \sqrt[3]{\frac{7 x^{2}}{6 y^{3} z^{5}}}\)

Answer

2. \(\begin{array}{l}{\log _{5} 8+2 \log _{5} a+6 \log _{5} b} {+\log _{5} c-3 \log _{5} d}\end{array}\)

4. \(\begin{array}{l}{\frac{1}{3}\left(\log _{6} 7+2 \log _{6} x-1-3 \log _{6} y\right.} {-5 \log _{6} z )}\end{array}\)

Exercise \(\PageIndex{24}\) Use the Properties of Logarithms

In the following exercises, use the Properties of Logarithms to condense the logarithm. Simplify if possible.

1. \(\log _{2} 56-\log _{2} 7\)
2. \(3 \log _{3} x+7 \log _{3} y\)
3. \(\log _{5}\left(x^{2}-16\right)-2 \log _{5}(x+4)\)
4. \(\frac{1}{4} \log y-2 \log (y-3)\)

Answer

2. \(\log _{3} x^{3} y^{7}\)

4. \(\log \frac{\sqrt[4]{y}}{(y-3)^{2}}\)

Exercise \(\PageIndex{25}\) Use the Change-of-Base Formula

In the following exercises, rounding to three decimal places, approximate each logarithm.

1. \(\log _{5} 97\)
2. \(\log _{\sqrt{3}} 16\)

Answer

2. \(5.047\)

Exercise \(\PageIndex{26}\) Solve Logarithmic Equations Using the Properties of Logarithms

In the following exercises, solve for \(x\).

1. \(3 \log _{5} x=\log _{5} 216\)
2. \(\log _{2} x+\log _{2}(x-2)=3\)
3. \(\log (x-1)-\log (3 x+5)=-\log x\)
4. \(\log _{4}(x-2)+\log _{4}(x+5)=\log _{4} 8\)
5. \(\ln (3 x-2)=\ln (x+4)+\ln 2\)

Answer

2. \(x=4\)

4. \(x=3\)

Exercise \(\PageIndex{27}\) Solve Exponential Equations Using Logarithms

In the following exercises, solve each exponential equation. Find the exact answer and then approximate it to three decimal places.

1. \(2^{x}=101\)
2. \(e^{x}=23\)
3. \(\left(\frac{1}{3}\right)^{x}=7\)
4. \(7 e^{x+3}=28\)
5. \(e^{x-4}+8=23\)

Answer

1. \(x=\frac{\log 101}{\log 2} \approx 6.658\)

3. \(x=\frac{\log 7}{\log \frac{1}{3}} \approx-1.771\)

5. \(x=\ln 15+4 \approx 6.708\)

Exercise \(\PageIndex{28}\) Use Exponential Models in Applications

1. Jerome invests $\(18,000\) at age \(17\). He hopes the investments will be worth $\(30,000\) when he turns \(26\). If the interest compounds continuously, approximately what rate of growth will he need to achieve his goal? Is that a reasonable expectation?
2. Elise invests $\(4500\) in an account that compounds interest monthly and earns \(6\)%.How long will it take for her money to double?
3. Researchers recorded that a certain bacteria population grew from \(100\) to \(300\) in \(8\) hours. At this rate of growth, how many bacteria will there be in \(24\) hours?
4. Mouse populations can double in \(8\) months \(\left(A=2 A_{0}\right)\). How long will it take for a mouse population to triple?
5. The half-life of radioactive iodine is \(60\) days. How much of a \(50\) mg sample will be left in \(40\) days?

Answer

2. \(11.6\) years

4. \(12.7\) months