Problem Set: Exponential and Logarithmic Functions

For the following exercises (1-4), evaluate the given exponential functions as indicated, accurate to two significant digits after the decimal.

1. [latex]f(x)=5^x[/latex]

a. [latex]x=3[/latex]

b. [latex]x=\dfrac{1}{2}[/latex]

c. [latex]x=\sqrt{2}[/latex]

2. [latex]f(x)=(0.3)^x[/latex]

a. [latex]x=-1[/latex]

b. [latex]x=4[/latex]

c. [latex]x=-1.5[/latex]

3. [latex]f(x)=10^x[/latex]

a. [latex]x=-2[/latex]

b. [latex]x=4[/latex]

c. [latex]x=\dfrac{5}{3}[/latex]

4. [latex]f(x)=e^x[/latex]

a. [latex]x=2[/latex]

b. [latex]x=-3.2[/latex]

c. [latex]x=\pi [/latex]

For the following exercises (5-10), match the exponential equation to the correct graph.

  1. [latex]y=4^{−x}[/latex]
  2. [latex]y=3^{x-1}[/latex]
  3. [latex]y=2^{x+1}[/latex]
  4. [latex]y=\left(\dfrac{1}{2}\right)^x+2[/latex]
  5. [latex]y=−3^{−x}[/latex]
  6. [latex]y=1-5^x[/latex]
5. An image of a graph. The x axis runs from -5 to 5 and the y axis runs from -2 to 8. The graph is of a decreasing curved function. The function decreases until it approaches the line “y = 2”, but never touches this line. The y intercept is at the point (0, 3) and there is no x intercept.

6. An image of a graph. The x axis runs from -4 to 4 and the y axis runs from -9 to 2. The graph is of a function that starts slightly below the line “y = 1” and begins decreasing rapidly in a curve. The x intercept and y intercept are both at the origin.

7. An image of a graph. The x axis runs from -5 to 5 and the y axis runs from -5 to 5. The graph is of a curved increasing function that starts slightly above the x axis and begins increasing rapidly. There is no x intercept and the y intercept is at the point (0, (1/3)). Another point of the graph is at (1, 1).

8. An image of a graph. The x axis runs from -5 to 5 and the y axis runs from -5 to 5. The graph is of a curved decreasing function that decreases until it comes close the x axis without touching it. There is no x intercept and the y intercept is at the point (0, 1). Another point of the graph is at (-1, 4).
9. An image of a graph. The x axis runs from -5 to 5 and the y axis runs from -5 to 5. The graph is of a curved increasing function that increases until it comes close the x axis without touching it. There is no x intercept and the y intercept is at the point (0, -1). Another point of the graph is at (-1, -3).

10.An image of a graph. The x axis runs from -5 to 5 and the y axis runs from -5 to 5. The graph is of a curved increasing function that starts slightly above the x axis and begins increasing rapidly. There is no x intercept and the y intercept is at the point (0, 2). Another point of the graph is at (-1, 1).

For the following exercises (11-17), sketch the graph of the exponential function. Determine the (a) domain, (b) range, and (c) horizontal asymptote.

11. [latex]f(x)=e^x+2[/latex]

12. [latex]f(x)=−2^x[/latex]

13. [latex]f(x)=3^{x+1}[/latex]

14. [latex]f(x)=4^x-1[/latex]

15. [latex]f(x)=1-2^{−x}[/latex]

16. [latex]f(x)=5^{x+1}+2[/latex]

17. [latex]f(x)=e^{−x}-1[/latex]

For the following exercises (18-25), write the equation in equivalent exponential form.

18. [latex]\log_3 81=4[/latex]

19. [latex]\log_8 2=\dfrac{1}{3}[/latex]

20. [latex]\log_5 1=0[/latex]

21. [latex]\log_5 25=2[/latex]

22. [latex]\log 0.1=-1[/latex]

23. [latex]\ln\left(\dfrac{1}{e^3}\right)=-3[/latex]

24. [latex]\log_9 3=0.5[/latex]

25. [latex]\ln 1=0[/latex]

For the following exercises (26-35), write the equation in equivalent logarithmic form.

26. [latex]2^3=8[/latex]

27. [latex]4^{-2}=\dfrac{1}{16}[/latex]

28. [latex]10^2=100[/latex]

29. [latex]9^0=1[/latex]

30. [latex]\left(\dfrac{1}{3}\right)^3=\dfrac{1}{27}[/latex]

31. [latex]\sqrt[3]{64}=4[/latex]

32. [latex]e^x=y[/latex]

33. [latex]9^y=150[/latex]

34. [latex]b^3=45[/latex]

35. [latex]4^{-3/2}=0.125[/latex]

For the following exercises (36-41), sketch the graphs of the logarithmic functions and determine their (a) domain, (b) range, and (c) vertical asymptote.

36. [latex]f(x)=3+\ln x[/latex]

37. [latex]f(x)=\ln(x-1)[/latex]

38. [latex]f(x)=\ln(−x)[/latex]

39. [latex]f(x)=1-\ln x[/latex]

40. [latex]f(x)=\log x-1[/latex]

41. [latex]f(x)=\ln(x+1)[/latex]

For the following exercises (42-47), use properties of logarithms to write the expressions as a sum, difference, and/or product of logarithms.

42. [latex]\log x^4y[/latex]

43. [latex]\log_3 \dfrac{9a^3}{b}[/latex]

44. [latex]\ln a\sqrt[3]{b}[/latex]

45. [latex]\log_5 \sqrt{125xy^3}[/latex]

46. [latex]\log_4 \dfrac{\sqrt[3]{xy}}{64}[/latex]

47. [latex]\ln\left(\dfrac{6}{\sqrt{e^3}}\right)[/latex]

For the following exercises (48-55), solve the exponential equation exactly.

48. [latex]5^x=125[/latex]

49. [latex]e^{3x}-15=0[/latex]

50. [latex]8^x=4[/latex]

51. [latex]4^{x+1}-32=0[/latex]

52. [latex]3^{x/14}=\dfrac{1}{10}[/latex]

53. [latex]10^x=7.21[/latex]

54. [latex]4·2^{3x}-20=0[/latex]

55. [latex]7^{3x-2}=11[/latex]

For the following exercises (56-63), solve the logarithmic equation exactly, if possible.

56. [latex]\log_3 x=0[/latex]

57. [latex]\log_5 x=-2[/latex]

58. [latex]\log_4 (x+5)=0[/latex]

59. [latex]\log(2x-7)=0[/latex]

60. [latex]\ln\sqrt{x+3}=2[/latex]

61. [latex]\log_6 (x+9)+\log_6 x=2[/latex]

62. [latex]\log_4(x+2)-\log_4(x-1)=0[/latex]

63. [latex]\ln x+\ln (x-2)=\ln 4[/latex]

For the following exercises (64-69), use the change-of-base formula and either base 10 or base [latex]e[/latex] to evaluate the given expressions. Answer in exact form and in approximate form, rounding to four decimal places.

64. [latex]\log_5 47[/latex]

65. [latex]\log_7 82[/latex]

66. [latex]\log_6 103[/latex]

67. [latex]\log_{0.5} 211[/latex]

68. [latex]{\text{log}}_{2}\pi [/latex]

69. [latex]\log_{0.2} 0.452[/latex]

70. Rewrite the following expressions in terms of exponentials and simplify.

a. [latex]2\cosh(\ln x)[/latex]

b. [latex]\cosh 4x+\sinh 4x[/latex]

c. [latex]\cosh 2x-\sinh 2x[/latex]

d. [latex]\ln(\cosh x+\sinh x)+\ln(\cosh x-\sinh x)[/latex]

71. [T] The number of bacteria [latex]N[/latex] in a culture after [latex]t[/latex] days can be modeled by the function [latex]N(t)=1300·2^{t/4}[/latex]. Find the number of bacteria present after 15 days.

72. [T] The demand [latex]D[/latex] (in millions of barrels) for oil in an oil-rich country is given by the function [latex]D(p)=150·2.7^{-0.25p}[/latex], where [latex]p[/latex] is the price (in dollars) of a barrel of oil. Find the amount of oil demanded (to the nearest million barrels) when the price is between $15 and $20.

73. [T] The accumulated amount [latex]A[/latex] of a $100,000 investment whose interest compounds continuously for [latex]t[/latex] years is given by [latex]A(t)=100,000·e^{0.055t}[/latex]. Find the amount [latex]A[/latex] accumulated in 5 years.

74. [T] An investment is compounded monthly, quarterly, or yearly and is given by the function [latex]A=P\left(1+\frac{j}{n}\right)^{nt}[/latex], where [latex]A[/latex] is the value of the investment at time [latex]t, \, P[/latex] is the initial principle that was invested, [latex]j[/latex] is the annual interest rate, and [latex]n[/latex] is the number of time the interest is compounded per year. Given a yearly interest rate of 3.5% and an initial principle of $100,000, find the amount [latex]A[/latex] accumulated in 5 years for interest that is compounded (a) daily, (b) monthly, (c) quarterly, and (d) yearly.

75. [T] The concentration of hydrogen ions in a substance is denoted by [latex][\text{H}^{+}][/latex], measured in moles per liter. The pH of a substance is defined by the logarithmic function [latex]\text{pH}=−\log[\text{H}^{+}][/latex]. This function is used to measure the acidity of a substance. The pH of water is 7. A substance with a pH less than 7 is an acid, whereas one that has a pH of more than 7 is a base.

(a) Find the pH of the following substances. Round answers to one digit. (b) Determine whether the substance is an acid or a base.

  1. Eggs: [latex][\text{H}^{+}]=1.6 \times 10^{-8}[/latex] mol/L
  2. Beer: [latex][\text{H}^{+}]=3.16 \times 10^{-3}[/latex] mol/L
  3. Tomato Juice: [latex][\text{H}^{+}]=7.94 \times 10^{-5}[/latex] mol/L

76. [T] Iodine-131 is a radioactive substance that decays according to the function [latex]Q(t)=Q_0·e^{-0.08664t}[/latex], where [latex]Q_0[/latex] is the initial quantity of a sample of the substance and [latex]t[/latex] is in days. Determine how long it takes (to the nearest day) for 95% of a quantity to decay.

77. [T] According to the World Bank, at the end of 2013 ([latex]t=0[/latex]) the U.S. population was 316 million and was increasing according to the following model:

[latex]P(t)=316e^{0.0074t}[/latex],

where [latex]P[/latex] is measured in millions of people and [latex]t[/latex] is measured in years after 2013.

  1. Based on this model, what will be the population of the United States in 2020?
  2. Determine when the U.S. population will be twice what it is in 2013.

78. [T] The amount [latex]A[/latex] accumulated after 1000 dollars is invested for [latex]t[/latex] years at an interest rate of 4% is modeled by the function [latex]A(t)=1000(1.04)^t[/latex].

  1. Find the amount accumulated after 5 years and 10 years.
  2. Determine how long it takes for the original investment to triple.

79. [T] A bacterial colony grown in a lab is known to double in number in 12 hours. Suppose, initially, there are 1000 bacteria present.

  1. Use the exponential function [latex]Q=Q_0e^{kt}[/latex] to determine the value [latex]k[/latex], which is the growth rate of the bacteria. Round to four decimal places.
  2. Determine approximately how long it takes for 200,000 bacteria to grow.

80. [T] The rabbit population on a game reserve doubles every 6 months. Suppose there were 120 rabbits initially.

  1. Use the exponential function [latex]P=P_{0} a^{t}[/latex] to determine the growth rate constant [latex]a[/latex]. Round to four decimal places.
  2. Use the function in part (a) to determine approximately how long it takes for the rabbit population to reach 3500.

81. [T] The 1906 earthquake in San Francisco had a magnitude of 8.3 on the Richter scale. At the same time, in Japan, an earthquake with magnitude 4.9 caused only minor damage. Approximately how much more energy was released by the San Francisco earthquake than by the Japanese earthquake?